Systems and method of high resolution three-dimesnsional imaging

ABSTRACT

Embodiments of the invention provide systems and methods for three-dimensional imaging with wide field of view and precision timing. In accordance with one aspect, a three-dimensional imaging system includes an illumination subsystem configured to emit a light pulse with a divergence sufficient to irradiate a scene having a wide field of view. A sensor subsystem is configured to receive over a wide field of view portions of the light pulse reflected or scattered by the scene and including: a modulator configured to modulate as a function of time an intensity of the received light pulse portion to form modulated received light pulse portions; and means for generating a first image corresponding to the received light pulse portions and a second image corresponding to the modulated received light pulse portions. A processor subsystem is configured to obtain a three-dimensional image based on the first and second images.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of the following applications, theentire contents of each of which are incorporated by reference herein:

U.S. Provisional Patent Application No. 61/117,788, filed Nov. 25, 2008and entitled “Method and Apparatus for a 3D Digital Imaging Device;”

U.S. Provisional Patent Application No. 61/121,096, filed Dec. 9, 2008and entitled “Method and Apparatus for Wide Field of View LargeAperture, Low Voltage Optical Shutter;” and

U.S. Provisional Patent Application No. 61/166,413, filed Apr. 20, 2009and entitled “Method and Apparatus for Large Divergence LaserIlluminator.”

FIELD OF THE INVENTION

This application generally relates to systems and methods ofthree-dimensional imaging.

BACKGROUND OF THE INVENTION

Digital electronics have made it possible to record a grey scale orcolor image of a scene, as a still image, as a series of still images,or as a video. A video is a series of still images that continues for anextended period of time with a specific interval between each image.Analog imaging utilizes photographic film to obtain an image, whereasdigital imaging utilizes a focal plane array (FPA) to obtain an imagewhich provides a signal in response to light illumination that is thendigitized. The FPA includes an array of light-detecting elements, orpixels, positioned at a focal plane of optics that image a scene. Muchrecent effort has been directed to improving the density, size,sensitivity, dynamic range, and noise characteristics of FPAs, as wellas the associated optics and electronics, enabling higher resolutionimages to be acquired. However, most FPAs by their nature cannot detectcolor, only the presence and quantity of light. Additional techniqueshave been developed to recreate the color seen by the human eye in acolor digital image, such as the use of Bayer filters as described inU.S. Pat. No. 3,971,065, and subsequent developments thereof, ormultiple FPAs with bandpass color filters. Other FPAs have beendeveloped that detect color directly.

Additionally, FPAs are limited to collecting information about lightemanating from a scene in two dimensions, horizontal (x) and vertical(y), in front of the imaging device, often referred to as thefield-of-view (FOV). Most FPAs cannot, by themselves, obtain informationabout the distance (z) of an object from the FPA without the use ofcomplex, high speed, expensive read-out circuits. A wide variety ofimaging techniques have been developed to attempt to extract, from atwo-dimensional image, information about the distance of a scene and ofthree-dimensional objects within that scene. Some such techniques may bebased on information in a single two-dimensional image, such asanalyzing the positions and depths of any shadows and the apparentposition and type of light source to infer information about thedistance of objects in the image. Other such techniques, often referredto stereoscopy or stereo photogrammetry, may be based on obtainingmultiple two-dimensional images with multiple cameras positioned atdifferent positions relative to the scene, and comparing informationwithin the images to deduce the ranges and three-dimensional features ofobjects within the scene. Both types of techniques typically arecomputational intensive, provide only limited information about thethree dimensional features of a scene, and may be unsuitable for movingobjects. Additionally, stereoscopy typically requires precise knowledgeof the relative position and angle at which the multiple two-dimensionalimages are obtained and so requires extensive calibration procedures andlimited flexibility. The multiple views also means that more lines ofsight will be obscured. This limits the use of such system inuncontrolled environments, can significantly increase the cost of anyimplementation, and limits the accuracy and precision of any calculateddistance values.

Another approach to obtaining distance information for objects in ascene is based on scanning a laser beam over the scene, and determiningthe ranges and three-dimensional shapes of objects in a scene based on aphase or temporal delay of the laser beam, following reflection from theobject. Specifically, the distance the laser beam travels from the lightsource, to a particular point in the scene, and then to a sensor can becalculated based on the phase delay or time of flight (TOF) of the laserbeam, and the speed of light. Distance and shape information aboutobjects in the scene may be obtained by scanning the laser beam, onepoint at a time, across the entire scene, and determining the phasedelay or TOF of the laser beam at each point. Such scanning may beaccomplished, for example, by moving mirrors or beam steering elementsto change the beam direction. As such, the maximum scanning speed may belimited by the amount of time required to make a measurement at eachpoint, and the speed of the mirror or beam steering element. Some suchlaser scanners are limited to processing tens of thousands to hundredsof thousands of points per second. Therefore, obtaining a highresolution image of a complex scene may take a large amount of time,although lowering the resolution of the image may reduce the timerequired to obtain the image. Image quality also may be degraded byperformance drift during the scan, or motion within the scene.Additionally, scanning merely provides the value of the distance at eachmeasurement point, resulting in what may be referred to as a “pointcloud;” often no color or intensity information is obtained, andadditional steps are required to transform the point cloud into adigital representation more suited to human interpretation. For example,color or grey-scale imagery may be collected in a separate step andcombined with the point cloud data if a complete 3-dimensional image isdesired.

U.S. Pat. No. 5,157,451 to Taboada et al. (“Taboada”), the entirecontents of which are incorporated herein by reference, describes analternative technique that combines digital imaging with distancemeasurements for long-range imaging of target objects. Specifically,Taboada discloses obtaining three-dimensional coordinates of a targetobject by irradiating the object with a laser pulse, and using a Kerrcell or Pockels cell to vary the polarization of the laser pulsereflected from the object as a function of time. As a result, thepolarization state of portions of the laser pulse reflected by featuresof the object nearer the imaging system (shorter TOF), is affected to asmall degree, while the polarization state of portions of the laserpulse reflected by features of the object further from the imagingsystem (longer TOF), will be affected more. By imaging the twopolarization components of the polarization-modulated laser beam ontotwo separate FPAs, positional information about the object may becalculated. However, the systems and methods disclosed by Taboada havelimited applicability, some of which are discussed further below.

As noted above, the system of Taboada utilizes a Kerr cell or Pockelscell, which are particular types of electro-optic modulators (EOMs), tomodulate the polarization of the reflected laser pulse. In an EOM, anelectric field is applied to a material that changes properties underthe influence of an electric field. The EOM's change in propertiesmodifies the phase of light transmitted therethrough. Pockels cells arebased on the Pockels effect, in which a material's refractive indexchanges linearly with applied electric field, while Kerr cells are basedon the Kerr effect, in which a material's refractive index variesquadratically with the electric field. For certain materials and certainorientations of applied electric field, the Pockels effect creates ananisotropy in the refractive index of the material. Such materials andfields may be used to create a Pockels cell, in which the inducedanisotropy changes the polarization state of light transmittedtherethrough linearly as a function of applied voltage. EOMs such asPockels cells may be placed between crossed polarizers to modulate theintensity of light, as is known to those of ordinary skill in the art.The temporal response of a Pockels cell may in some circumstances beless than 1 nanosecond, enabling its use as a fast optical shutter.

Although widely used for laser applications, Pockels cells traditionallyhave been viewed as having significant limitations, rendering suchdevices unsuitable for optical switching in other types of applications.For example, in some applications, the incident light may contain alarge range of angles. However, typical Pockels cells may onlyeffectively modulate incident light deviating by less than about 1degree from the surface normal, significantly limiting their use in suchapplications. Additionally, Pockels cells may require high electricfields, e.g., in excess of several kilovolts, to sufficiently rotate thepolarization of light passing therethrough. The electronics required togenerate such fields may be expensive and cumbersome. One approach forreducing the voltage required to drive the Pockets cell has been to usea transverse electric field and a transversely oriented Pockets cell.The phase change induced in such a cell is proportional to the ratio ofthe crystal thickness d (which is also the separation between theelectrodes) to the crystal length L as given by:

$\begin{matrix}{V \propto \frac{\lambda \; d}{2\; n^{3}r_{ij}L}} & (1)\end{matrix}$

where V_(1/2) is the half-wave voltage, i.e., the voltage required toinduce a phase delay of π in light of one polarization relative toorthogonally polarized light, λ is the wavelength of light, n is therefractive index of the crystal, and r_(ij) is the electro-optic tensorcoefficient of the crystal. Reducing the thickness of the electro-opticcrystal to bring the electrodes closer together may reduce the voltage,but also may reduce the clear aperture of the Pockels cell and may causevignetting, e.g., loss of information at the edges of the image,reducing image quality. New materials are being sought that may functionsatisfactorily at lower voltages, such as periodically poled lithiumniobate.

SUMMARY OF THE INVENTION

The present invention provides systems and methods of high resolutionthree-dimensional imaging, including those having a wide field of viewand adjustable depth of field. Specifically, the systems and methodscapture information about the ranges and shapes of multiple objects in ascene, which may be positioned at a variety of distances, with highresolution, e.g., sub-centimeter distance resolution.

In accordance with one aspect of the invention, a three-dimensionalimaging system includes an illumination subsystem configured to emit alight pulse with a divergence sufficient to irradiate a scene having awide field of view. The system further includes a sensor subsystemconfigured to receive over a wide field of view portions of the lightpulse reflected or scattered by the scene, the sensor subsystemcomprising: a modulator configured to modulate as a function of time anintensity of the received light pulse portions to form modulatedreceived light pulse portions; and means for generating a first imagecorresponding to the received light pulse portions and a second imagecorresponding to the modulated received light pulse portions. The systemfurther includes a processor subsystem configured to obtain athree-dimensional image based on the first and second images.

In some embodiments, the means for generating comprises first and seconddiscrete arrays of light sensors, and optionally further includes animage constructor. The first and second discrete arrays of light sensorsmay be registered with one another. In other embodiments, the means forgenerating includes a single array of light sensors.

In some embodiments, the light pulse has a duration of less than 2nanoseconds, or less than 1 nanosecond. In some embodiments, thedivergence is between 1 and 180 degrees, for example, between 5 and 40degrees. In some embodiments, the illumination subsystem comprises alow-coherence laser configured to generate light containing a sufficientnumber of modes to produce a smooth spatial profile. In someembodiments, the low-coherence laser comprises an active fiber corehaving a diameter greater than 50 μm. In some embodiments, the lightpulse contains a visible wavelength. In some embodiments, the lightpulse contains a near-infrared wavelength. In some embodiments, thenear-infrared wavelength is between 1400 nm and 2500 nm. In someembodiments, the light pulse has a substantially uniform spatialprofile. In some embodiments, the light pulse further has asubstantially smooth temporal profile.

In some embodiments, the receiving lens has a diameter of at least 1inch, or of at least 2 inches. In some embodiments, the modulator has aclear aperture of at least 0.5 inches, or at least 1 inch.

In some embodiments, the modulator comprises a Pockets cell. Forexample, the modulator may include a Pockets assembly comprising: astack of transverse Pockets cells, each transverse Pockets cellcomprising a slab of electro-optic material and first and secondelectrodes respectively disposed on opposing major surfaces of the slab;a first conductor in electrical contact with the first electrode of eachtransverse Pockets cell; a second conductor in electrical contact withthe second electrode of each transverse Pockets cell; and a voltagesource in electrical contact with the first and second conductors. Insome embodiments, the voltage source applies a voltage of less than 100V across the first and second electrodes of each transverse Pockets cellvia the first and second conductors. In some embodiments, the voltagesource applies a voltage of less than 25 V across the first and secondelectrodes of each transverse Pockets cell via the first and secondconductors. In some embodiments, the electro-optic material is selectedfrom the group consisting of potassium dihydrogen phosophate (KDP),potassium dideuterium phosphate (KD*P), lithium niobate (LN),periodically poled lithium niobate, lithium tantalate, rubidium titanylphosphate (RTP), beta-barium borate (BSO) and isomorphs thereof. In someembodiments, the slab has a thickness less than 100 μm. In someembodiments, the first and second electrodes comprise a transparentconductor. The transparent conductor may have a refractive index that isapproximately the same as a refractive index of the electro-opticmaterial. In some embodiments, the Pockels assembly has a length Lapproximately equal to

${L = {m\frac{4\; d^{2}n}{\lambda}}},$

where m is an integer, d is a thickness of the slab, n is a number oftransverse Pockets cells in the assembly, and λ is a wavelength of thelight pulse.

In some embodiments, the processor subsystem comprises a controllerconfigured to send a control signal to the modulator, the modulatorconfigured to modulate the received light pulse portions monotonicallyas a function of time responsive to the control signal. In someembodiments, the processor subsystem may comprise discrete off-the-shelfcomponents. In some embodiments, the processor subsystem comprises acontroller configured to send a control signal to the modulator, themodulator configured to modulate the received light pulse portionsnon-monotonically as a function of time responsive to the controlsignal. In some embodiments, the modulator has a response function thatis a function of time and voltage, and the system stores informationcharacterizing the response function of the modulator. Some embodimentsfurther include a compensator configured to increase an acceptance angleof the modulator.

In some embodiments, the means for generating comprises a polarizingbeamsplitter. In other embodiments, the means for generating comprises aprism. In some embodiments, the means for generating includes at leastone focal plane array comprising a plurality of pixels, each pixelhaving a well depth of 100,000 or more electrons. In some embodiments,the means for generating includes at least one focal plane arraycomprising a plurality of pixels, and further includes a filter having aplurality of regions, each region positioned in front of a pixel andconfigured to attenuate light transmitted to that pixel in apredetermined fashion. In some embodiments, the system stores a matrixcharacterizing the filter.

In some embodiments, the sensor subsystem further comprises a broadbandor multiband (e.g., visible) imaging subsystem comprising: an imagesensor configured to obtain a broadband or multiband image of the scene;and an optic configured to direct a portion of the received light to theimage sensor. The processor subsystem may configured to combine thethree-dimensional image with the broadband or multiband image togenerate an image of the scene.

In some embodiments, at least one of the first and second imagescontains a region of maximum intensity, wherein the means for generatingcomprises a sensor array having a saturation limit, and wherein thesystem is configured to enhance a dynamic range of the three dimensionalimage by increasing an energy of the light pulse above the saturationlimit of the sensor array.

In some embodiments, at least one of the first and second imagescontains a region of maximum intensity, the means for generatingcomprises a sensor array having a saturation limit, and the processorsubsystem is configured to: send a first control signal to theillumination subsystem, the first control signal comprising aninstruction to generate a light pulse having a first energy selectedsuch that the region of maximum intensity is at or above a thresholdpercentage of the saturation limit of the sensor array but below thesaturation limit; and obtain a first three-dimensional image based onreflected or scattered portions of the light pulse having the firstenergy. The processor subsystem further may be configured to: send asecond control signal to the illumination subsystem, the second controlsignal comprising an instruction to generate a light pulse having asecond energy selected such that the region of maximum intensity isabove the saturation limit of the sensor array; and obtain a secondthree-dimensional based on reflected or scattered portions of the lightpulse having the second energy. The processor subsystem further may beconfigured to combine the first and second three-dimensional images toobtain a third three-dimensional image having increased resolutioncompared to the first and second three-dimensional images. In someembodiments, the second energy is selected such that the region ofmaximum intensity is at least 4 times above the saturation limit of thefocal plane array.

In some embodiments, the processor subsystem is configured to: instructthe illumination subsystem to emit a plurality of light pulses; adjust atiming of the modulator such that modulation begins at a different timefor each light pulse of the plurality of light pulses; obtain aplurality of three-dimensional images corresponding to each light pulseof the plurality of light pulses; and obtain an enhancedthree-dimensional image based on the plurality of three-dimensionalimages, the enhanced three-dimensional image corresponding to a largerdistance window than a distance window of any of the plurality ofthree-dimensional images.

In some embodiments, the processor subsystem is configured to: send afirst control signal to the illumination subsystem, the first controlsignal comprising an instruction to generate a first light pulse; send asecond control signal to the modulator, the second control signalcomprising an instruction to modulate received portions of the firstlight pulse over a first temporal window; obtain a firstthree-dimensional image based on the modulated portions of the firstlight pulse; send a third control signal to the illumination subsystem,the third control signal comprising an instruction to generate a secondlight pulse; send a fourth control signal to the modulator, the fourthcontrol signal comprising an instruction to modulate received portionsof the second light pulse over a second temporal window; obtain a secondthree-dimensional image based on the modulated portions of the secondlight pulse; and combine the first and second three-dimensional imagesto obtain a third three dimensional image having increased range ascompared to the first and second three-dimensional images. The first andsecond temporal windows may overlap with one another. The first temporalwindow may have a shorter duration than the second temporal window. Thefirst temporal window may have a different start time than the secondtemporal window.

In some embodiments, the three-dimensional image has subcentimeterresolution.

In accordance with another aspect of the present invention, a method ofthree-dimensional imaging includes: emitting a light pulse having adivergence sufficient to irradiate a scene having a wide field of view;receiving over a wide field of view portions of the light pulsereflected or scattered by the scene; modulating with a modulator thereceived light pulse portions as a function of time to form modulatedreceived light pulse portions; generating a first image corresponding tothe received light pulse portions; generating a second imagecorresponding to the modulated received light pulse portions; andobtaining a three-dimensional image of the scene based on the first andsecond images.

In some embodiments, generating the first image comprises adding thesecond image to a third image. In some embodiments, modulating with themodulator comprises modulating a polarization state of the receivedlight pulse portions.

In accordance with another aspect of the present invention, a modulatorfor modulating the polarization of light having a wavelength includes: astack of transverse Pockels cells, each transverse Pockels cellcomprising a slab of electro-optic material and first and secondelectrodes respectively disposed on opposing major surfaces of the slab;a first conductor in electrical contact with the first electrode of eachtransverse Pockels cell; a second conductor in electrical contact withthe second electrode of each transverse Pockels cell; and a voltagesource in electrical contact with the first and second conductors, theslab of each transverse Pockets cell having a length L approximatelyequal to

${L = {m\frac{4\; d^{2}n}{\lambda}}},$

where m is an integer, d is a thickness of the slab, and n is a numberof transverse Pockels cells in the stack.

In some embodiments, the voltage source applies a voltage of less than100 V across the first and second electrodes of each transverse Pockelscell via the first and second conductors. In some embodiments, thevoltage source applies a voltage of less than 25 V across the first andsecond electrodes of each transverse Pockets cell via the first andsecond conductors. In some embodiments, the electro-optic material isselected from the group consisting of potassium dihydrogen phosophate(KDP), potassium dideuterium phosphate (KD*P), lithium niobate (LN),periodically poled lithium niobate, lithium tantalate, rubidium titanylphosphate (RTP), beta-barium borate (BBO) and isomorphs thereof. In someembodiments, the electro-optic material comprises periodically poledlithium niobate. In some embodiments, the slab has a thickness less than100 μm. In some embodiments, the first and second electrodes comprise atransparent conductor. In some embodiments, the wavelength is in thevisible range. In some embodiments, the wavelength is in thenear-infrared range. In some embodiments, the wavelength is between 1400nm and 2500 nm. In some embodiments, the modulator has an acceptanceangle of at least 40 degrees. In some embodiments, the modulator has anacceptance angle of at least 5 degrees. In some embodiments, themodulator has an acceptance angle of at least 1 degree. In someembodiments, the modulator further has a clear aperture of at least 1inch, for example, of at least 2 inches.

In accordance with yet another aspect of the present invention, amodulator for modulating the polarization of light includes: a stack oftransverse Pockels cells, each transverse Pockels cell comprising a slabof electro-optic material and first and second electrodes respectivelydisposed on opposing major surfaces of the slab; a first conductor inelectrical contact with the first electrode of each transverse Pockelscell; a second conductor in electrical contact with the second electrodeof each transverse Pockels cell; and a voltage source in electricalcontact with the first and second conductors, the first and secondconductors comprising a transparent conductor having approximately thesame refractive index as does the electro-optic material.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a perspective view of a system for obtaining athree-dimensional image of a scene, according to some embodiments of thepresent invention.

FIG. 2 schematically illustrates the monotonic polarization modulationof light pulse portions reflected from the scene of FIG. 1.

FIG. 3 schematically illustrates two-dimensional and three-dimensionalimages formed using the modulated light pulse portions from FIG. 2.

FIG. 4 illustrates an overview of a method of obtaining athree-dimensional image of a scene, according to some embodiments of thepresent invention.

FIG. 5 schematically illustrates components in the system of FIG. 1,according to some embodiments of the present invention.

FIG. 6A illustrates a light source for generating spatially uniformlight pulses having duration of less than 1 nanosecond, according tosome embodiments of the present invention.

FIGS. 6B-6C schematically illustrate spatial and temporal modestructures of the light source of FIG. 6A, according to one embodimentof the present invention.

FIG. 7A illustrates a perspective view of a wide-aperture, low-voltagePockels assembly, according to some embodiments of the presentinvention.

FIG. 7B illustrates a perspective view of an alternative wide-aperture,low-voltage Pockels assembly, according to some embodiments of thepresent invention.

FIG. 7C illustrates a perspective view of an alternative wide-aperture,low-voltage Pockels assembly, according to some embodiments of thepresent invention.

FIG. 8 illustrates steps in a method for increasing the informationcontent of a three-dimensional image, according to some embodiments ofthe present invention.

FIG. 9A schematically illustrates a color filter that may be used toincrease the dynamic range of a focal plane array used in athree-dimensional imaging system, according to some embodiments of thepresent invention.

FIG. 9B illustrates transmission spectra of a commercially availablecolor filter that may be used to increase the dynamic range of a focalplane array, according to some embodiments of the present invention.

FIG. 10 illustrates steps in a method of extending the range of athree-dimensional image, according to some embodiments of the presentinvention.

FIG. 11 schematically illustrates an alternative embodiment of athree-dimensional imaging system, according to some embodiments of thepresent invention.

FIG. 12 schematically illustrates an alternative embodiment of athree-dimensional imaging system, according to some embodiments of thepresent invention.

DETAILED DESCRIPTION 1. Overview

Embodiments of the invention provide systems and methods for obtaininghigh resolution images of scenes, including wide field of view scenes.Specifically, the systems and methods may simultaneously record threedimensional position information for multiple objects in a scene withhigh spatial and distance resolution, along with intensity (grey-scaleor color) information about the scene. This information, both coordinateand intensity, is recorded for every pixel in an array of pixels foreach image. The intensity and position information are combined into asingle three-dimensional image that approximates a human view of thescene, and which further records the three-dimensional coordinates ofthe shape and relative position of each object in the scene. A series ofsuch images may be acquired in similar fashion to a digital videocamera, providing a “movie” of changes in the scene over time, eachthree-dimensional image in the movie being referred to as a frame. Inmany circumstances, the scene being imaged may include many objects at avariety of distances from the system. The inventive system records thethree-dimensional coordinate and intensity of the portion of an objectcorresponding to each pixel element, thus providing the threedimensional shape of each individual object in the scene as well as theoverall coordinates, with respect to the three-dimensional imagingdevice as well as other portions of the scene in the image recorded bythe three dimensional imaging device, of the objects in the scene. If anabsolute frame of reference is desired, a GPS unit or other suitablemeans for fixing the absolute position of the imaging system may beincluded.

One aspect of this invention provides the ability to recordthree-dimensional information and color or monochrome imagery for a widevariety of scenes, with particular attention to those that include closeobjects. For short-range imaging applications (e.g., objects nearer than1 km), it is often useful to observe objects distributed across a largespatial region. This translates to a need for a wide field of view(FOV). In the context of the present invention, a “wide field of view”refers to a field subtending an angle of one degree or greater. Thefield of view is typically expressed as the angular separation betweenthe sides of a scene. For some uses of the systems and methods describedherein, FOVs of greater than 1 degree, or greater than 5 degrees, orgreater than 10 degrees, are useful because they may enhance theinformation content of a scene, e.g., by providing information about thecontext of an object. Previously known systems have been unable toachieve such wide FOVs.

For example, Taboada describes a technique for imaging thethree-dimensional coordinates of a single, distant target and amonotonic polarization ramp. This maps the temporal features of thereturned light pulse from the target onto a characteristic intensityrange which can be readily measured by a pair of video cameras. Whilethis simple technique is adequate to obtain some depth information ondistant objects, several improvements may be made. Embodiments of thepresent invention provide several areas of improvement over thatdescribed by Taboada. These areas may be important, as the inventivesystems and methods may be used to record three-dimensional informationabout several objects within a scene, particularly as the distance fromthe system and the objects becomes shorter. The embodiments may employany one, or a combination of any, of these areas of improvement,including the provision of high dynamic range, adaptive depth of field,wide field of view, high resolution, frame-to-frame registration, aswell as others.

FIG. 1 illustrates a perspective view of a system 100 for obtaining athree-dimensional, wide FOV image of a scene 190, according to someembodiments of the present invention. Greater detail of methods ofobtaining a three dimensional image of a scene using a system such assystem 100 are provided below in the section entitled “Methods,” andgreater detail of the components of a system such as system 100 areprovided below in the section entitled “Systems.” Although theillustrated embodiment is described with reference to the Cartesiancoordinate system, other coordinate systems may be used.

As illustrated in FIG. 1, system 100 includes illumination subsystem110, sensor subsystem 120, processing subsystem 140, and body 150 inwhich the various subsystems are mounted. Body 150 may further include aprotective cover, not shown. The particular form of system 100 may varydepending on the desired performance parameters and intendedapplication. For example, if system 100 is intended for household use,it will preferably be sufficiently small and light as to be held by asingle hand, similar to a camcorder, and may be configured to recordrelatively close scenes with a modest resolution. Alternatively, ifsystem 100 is intended for surveying a building site, then it may beconfigured to image large and/or distant scenes with high resolution,and the size of the system will be of secondary consideration.

Illumination subsystem 110 includes a light source, not shown in FIG. 1but described in greater detail below, and transmission lens 112, whichmay include a single lens, a compound lens, or a combination of lenses.The light source is configured to generate light pulse 119, whichpreferably has duration of 2 nanoseconds or less, for example, between 1nanosecond and 50 picoseconds, depending on the desired resolution inthe z-direction. Transmission lens 112 is configured to increase thedivergence of pulse 119 to an angle φ of 1 degrees or greater, forexample between 1 and 180 degrees, or between 1 and 120 degrees, orbetween 2 and 90 degrees, or between 2 and 40 degrees, or between 5 and40 degrees, and to direct the pulse toward the scene such that the pulseirradiates a portion of scene 190 to be imaged. Objects 191 and 192 inscene 190 are each at different positions in the x-, y-, andz-directions in a Cartesian coordinate system, (or in the r- andΘ-directions in a spherical coordinate system) and also have differentshapes. As such, different portions of the laser pulse will traveldifferent distances to irradiate the objects 191, 192, as well as toirradiate different features or areas of each object individually,before the objects scatter and/or reflect the pulse portions 127, 128,129 back toward system 100. As such, each of pulse portions 127, 128,and 129 will have a different time of flight (TOF). Additionally, thepulse portions 127, 128, 129 have different intensities, depending onthe reflectivity of the irradiated feature of each object, and the angleof that feature relative to system 100.

Sensor subsystem 120 includes large-aperture receiving lens 121 thatcollects reflected pulse portions 127, 128, 129. The appropriateaperture size will depend on the particular application, and may bebetween, for example, less than 1 cm and 2.5 cm. Other portions of thereflected pulse, e.g., those portions illustrated by dash-dot lines thatare reflected in directions other than back toward system 100, may notbe captured by receiving optics 121. As for transmission lens 112,receiving lens 121 may include a single lens, a compound lens, or acombination of lenses or other reflective or refractive elements.Receiving optics 121 may also collect broadband or multiband (e.g.,visible) information about scene 190, e.g., ambient light that scene 190scatters or reflects towards receiving optics 121. As such, for thiscase receiving lens 121 preferably is configured to reduce or eliminatepossible aberrations known in the art of optical system design that maydegrade image quality for one or more of the bands received.Alternatively, a separate receiving lens may be provided to receive thebroadband or multiband light. As described in greater detail below,sensor subsystem may include a separate visible imaging subsystem thatrecords a color or grey-scale image of scene 190 based on visible lightcollected from the scene. Such an image may later be combined withposition and shape information about the scene.

Sensor subsystem 120 creates a plurality of images based on pulseportions 127, 128, 129 that receiving lens 121 collects. These imagescontain positional information about objects 191, 192 in scene 190. Tocreate such images, sensor subsystem varies the polarization state ofthe incoming pulse portions 127, 128, 129 as a function of time, e.g.,using the wide field of view Pockels assembly described in greaterdetail below. When followed by an analyzer (e.g. a polarizing elementplaced after the Pockels cell), the corresponding transmission throughthe analyzer varies as a function of time. For example, as illustratedin FIG. 2, sensor subsystem 120 may vary the transmission 200 throughthe analyzer of light collected by receiving lens 121 from zero to onebetween times of 50 to 100 nanoseconds (where zero nanosecondscorresponds to the time the light pulse was generated). As such, pulseportions 127, 128, and 129, which are delayed in time relative to oneanother because they traveled different distances to and from objects inscene 190, experience different degrees of transmission than oneanother. Specifically, pulse portion 129 reflected from a closer portionof object 191 than did pulse portion 128, and so experiences lesstransmission than pulse portion 128. Pulse portion 127 reflected fromfurther object 192, and so experiences more transmission than pulseportion 128. As such, the extent to which sensor subsystem 120 modulatesthe transmission of a pulse portion, encodes the TOF of that pulseportion on the intensity received by the FPA, and thus the distance thatthe pulse portion traveled to and from a particular feature of an objectin a scene.

Sensor subsystem 120 determines the extent of polarization of each pulseportion 127, 128, 129 by splitting each pulse into its orthogonalpolarization components (e.g., H- and V-polarized components) using anoptical element such as a prism or polarizing beamsplitter, and thenrecording complementary images of the two polarization components. Forexample, as illustrated in FIG. 3, a first image 201 containsinformation about the H-polarized component of pulse portions 127, 128,129, in the form of intensity regions 227, 228, 229, respectively. Asecond image 201′ contains information about the V-polarized componentof pulse portions 127, 128, 129 in the form of intensity regions 227′,228′, 229′, respectively. Intensity region 229 in image 201 issignificantly darker than intensity region 229′ in image 201′ because,as illustrated in FIG. 2, pulse portion 129 arrived relatively early andexperienced relatively little polarization modulation. Conversely,intensity region 227 in image 201 is significantly darker than intensityregion 227 in image 201′ because pulse portion 127 arrived relativelylate and experienced significant polarization modulation. Intensityregions 228 and 228′ are approximately the same intensity, because pulseportion 128 arrived approximately midway through the modulation 200 ofthe polarization, and thus contained approximately equal amounts oforthogonal polarization components (e.g., H- and V).

Processor subsystem 140, illustrated in FIG. 1, may store images 201,201′ and perform further processing to obtain distance and shapeinformation for objects 191, 192 in scene 190. For example, as describedin greater detail below, processor subsystem 140 may normalize images201, 201′ to compensate for variations in reflectance or scatteringbetween objects 191, 192. Processor subsystem 140 may then calculate thepositions and shapes of different objects in scene 190 based on thenormalized images, forming three-dimensional image 300 illustrated inFIG. 3, which includes distance information about objects 191, 192.Image 300 includes object regions 327, 328, 329 that correspond to pulseportions 127, 128, 129 respectively, and include position and shapeinformation about objects 191 and 192. Further, processor subsystem 140may combine the calculated distance information with the white lightimage to provide a three-dimensional image of scene 190 that includesgrayscale or color information about the scene, thus mimicking a humanview of the scene. Processor subsystem 140 may further control andcoordinate the operation of illumination subsystem 110 and sensorsubsystem 120, as described in further detail below.

In one illustrative embodiment, system 100 has a range resolution ofabout 1 mm at a range of 20 meters, and a range resolution of about 3 mmor less at a range of 100 meters. The data acquisition rate may be, forexample, between 30-1000 million points per second, significantly fasterthan possible with scan-based devices. The angular resolution may be,for example, about 0.02 degrees, with a field of view of 30 to 45degrees. The device may be the size of a “bread box” or smaller, or evenin some embodiments the size of a “coffee cup” or smaller, with a costof less than about $10,000, or even less than $1,000.

Although system 100 is in some respects similar to that disclosed byTaboada, it differs in many material respects. First, Taboada is silenton the dynamic range, distance resolution, and optical resolution of hissystem, both of which are important to implementing a commerciallyviable imaging system, particularly one designed to collect informationabout multiple objects that may be positioned at different ranges withina scene. In contrast, as described in greater detail herein, system 100may be configured to obtain images of any desired resolution of anyaspect of a scene, for example, by extending the dynamic range of thesystem using any or all of a variety of techniques. Additionally,Taboada's system appears generally to be limited to acquiring along-range image of a single remote object, e.g., as may be viewed froman aircraft. For example, Taboada discloses the use of a previouslyknown Kerr cell or Pockels cell to modulate the polarization of thereflected light, in particular an arrangement of Pockels cells that arearranged optically in series with one another and electrically inparallel. Previously known Pockels cells may require voltages ofanywhere from several thousand to tens of thousands of volts, have asmall aperture, e.g., 1 cm or smaller, and have a low acceptance angle,e.g., a small fraction of 1 degree. Taboada's disclosed arrangement ofoptically serial and electrically parallel Pockels cells would furtherreduce the clear aperture and the acceptance angle, albeit requiring alower voltage. Thus, Taboada's system would be unable to obtain accuratedistance information using light that diverged by more than some smallfraction of 1 degree off of the surface normal of the Pockels cell, letalone 5 degrees or greater. In contrast, as described in greater detailbelow, system 100 includes a modulator enabling acquisition of highresolution distance information using light that diverges by between 5and 50 degrees, light scattered from objects distributed throughout awide field of view, and may require significantly lower voltages, e.g.,on the order of tens of volts, or even less than ten volts.

First, an overview of methods for obtaining a three-dimensional image ofa scene will be provided. Then, a system for obtaining three-dimensionalimages will be described in detail. Then, various potential applicationsof three-dimensional imaging will be described. Lastly, some examples ofalternative embodiments will be described. The described methods,systems, applications, and embodiments are intended to be merelyexemplary, and not limiting.

2. Methods

Methods for obtaining three dimensional images, according to variousembodiments of the present invention, e.g., system 100, will now bedescribed with reference to FIG. 4.

Method 400 illustrated in FIG. 4 includes generating a light pulsehaving, for example, a duration of less than 2 nanoseconds and a widefield of view (410), followed by irradiating the scene with such a pulse(420). Such a light pulse may be generated, for example, by one of theillumination subsystems described herein, or any other suitable lightpulse generator.

Preferably, the light pulse is spatially uniform. By “spatiallyuniform,” it is meant that the light pulse's spatial intensity, in thex-y plane, varies by less than about 50%, or by less than 40%, or byless than 30%, or by less than 20%, or by less than 10%, or by less than5%, or by less than 2%, over the majority of the spatial profile of thebeam. For example, the pulse may be characterized as having a “fullwidth at half maximum” (FWHM), determined by identifying the maximumintensity of the beam, and identifying the spatial extent of the beamhaving half that intensity or greater. In some embodiments, the spatialintensity of the pulse varies by less than 50%, or by less than 40%, orby less than 30%, or by less than 20%, or by less than 10%, or by lessthan 5%, or by less than 2%, over the spatial region characterized bythe FWHM. In other embodiments, the spatial intensity profile may varyby greater than 50%, or even by 100%. As described in greater detailbelow, in some embodiments such a spatially uniform light pulse may begenerated with a pulsed laser having a large number of spatial modes,e.g., greater than 20 spatial modes.

The temporal profile of the pulse generated by such a laser may also besubstantially smooth, meaning that the pulse's intensity, as a functionof time, varies smoothly. As described in greater detail below, in someembodiments such a temporally uniform light pulse may be generated witha pulsed laser having a large number of temporal modes, e.g., greaterthan 20 temporal modes.

The light pulse may be generated within any suitable portion of theelectromagnetic spectrum, e.g., in the visible portion of the spectrum(400 nm-700 nm), or in the near-infrared portion of the spectrum (700nm-2500 nm), or another range in the electromagnetic spectrum.Preferably, the laser's pulse energy is sufficiently high to provide anacceptable amount of signal to characterize a scene of interest, whileat the same time being sufficiently low to be eye-safe for users of thesystem and any occupants of the scene without the need for specialprecaution. For example, wavelengths greater than 1400 nm, e.g., between1400 nm and 2500 nm, may provide an increase of approximately thousandtimes the maximum permissible exposure limits as compared to visiblewavelengths, meaning the scene may be safely irradiated with a thousandtimes more energy with a pulse having a wavelength greater than 1400 nmthan with a pulse having a wavelength in the visible band. Other ways ofachieving eye safety include administrative controls, high divergence,and low spatial coherence.

It should be appreciated that the duration and divergence of the lightpulse may be selected based on the particular application. For example,a 1 nanosecond pulse may be used to achieve a distance resolution of0.01 meters, while a 100 picosecond pulse may be used to achieve adistance resolution of 0.001 meters. In various embodiments, theduration of the light pulse may be, for example, between 1 nanosecondand 10 picoseconds, or between 500 picoseconds and 50 picoseconds, orbetween 200 picoseconds and 100 picoseconds, or between 100 picosecondsand 10 picoseconds, depending on the desired distance resolution.Additionally, the wider the field of view desired for imaging at aparticular distance, the larger degree (angle γ in FIG. 1) of divergencemay be selected. For some purposes, a more modest resolution, field ofview, and range may be acceptable, while for other purposes, anextremely high resolution, field of view, and range may be desired. Asdescribed in greater detail below, the transmission optics may include amanually or automatically controlled zoom lens for adjusting thedivergence of the light pulse as needed to irradiate a desired field ofview of the particular scene to be imaged.

Method 400 includes collecting portions of the light pulse reflected andscattered by the scene with a large-aperture lens (430). As describedabove, the light pulse portions carry several types of information aboutthe scene. For example, although the scene is irradiated with a singlepulse, the receiving lens receives pulse portions having a variety ofTOFs, depending on the relative positions and shapes of differentobjects or different portions of an object in the scene.

Method 400 also includes modulating the polarization of the collectedlight pulse portions as a function of time (440). Such modulation may,for example, be a monotonic function of time, as illustrated in FIG. 2.In such an embodiment, pulses with a shorter TOF will experience lesspolarization modulation than pulses with a longer TOF, enabling distanceinformation to easily be obtained. However, as described in greaterdetail below, such modulation need not necessarily be monotonic.Additionally, the intensity, rather than the polarization, of thecollected light pulse portions, may be modulated.

For embodiments in which the polarization is modulated as a monotonicfunction of time, the distance information that may be obtained from aparticular image of a scene is based, in part, on the temporal durationof that modulation. For example, referring again to FIG. 2, thetransmission varies from zero to one over the span of 50 nanoseconds,beginning at 50 nanoseconds. As such, only pulse portions arrivingduring that 50 nanosecond modulation window (corresponding to a rangewindow of 7.5 meters) will experience a transmission between zero andone. Pulse portions that reflect from objects closer than 7.5 meters,and thus arrive before the modulation window begins at 50 nanoseconds,or that reflect from objects further than 30 meters, and thus arriveafter the modulation window has closed, will have longer or shorterTOFs, and so will not be modulated by the particular waveform in FIG. 2.To access other range windows, the start time and/or the temporalduration of the polarization modulation may be varied appropriately. Inone embodiment, method 400 is repeated using a variety of temporaldurations and/or start times for the polarization modulation, and theresulting images combined to form a three-dimensional image havingsignificantly greater distance information than could be obtained usinga single polarization modulation.

Method 400 also includes obtaining complementary images of theorthogonal polarization components (e.g., the H- and V-polarizationcomponents, or left and right circularly polarized components) of themodulated pulse portions (450). In one embodiment, such images areobtained by dividing the pulse portions into their orthogonal componentsusing a polarizing beamsplitter, and imaging the orthogonal componentsonto respective focal plane arrays (FPAs). The FPAs may be adapted tohave a high sensitivity at or near the central wavelength of the lightpulse generated at step 410. Where the light pulse is in the visibleband (e.g., 400 to 700 nm), a commercially available CCD or CMOS-basedarray may be suitable, whereas if the light pulse is in thenear-infrared band (e.g., 700 nm to 2500 nm), other array technology ormaterials may be required.

Method 400 also includes normalizing and combining the complementaryimages from step 450 to obtain distance and shape information forobjects in the scene (460). Such processing may be done on apixel-by-pixel basis, as described in greater detail below.

The range resolution obtainable via such a method, or by a systemconfigured to implement such a method, e.g., system 500 discussed belowwith reference to FIG. 5, may be based in part on the length of themodulation waveform combined with the uncertainty involved in measuringthe irradiance and timing of that waveform. The uncertainty in theirradiance measurement is related to the signal-to-noise ratio (SNR).For long-range applications such as disclosed by Taboada, the number ofphotons received from a target is limited because of the long distances,as the signal falls off as 1/R², where R is the distance to the target.The dominant noise terms are then related to the dark current, readoutnoise, and background light (e.g., sunlight). For such applications, theuse of very low noise imaging arrays may be crucial. In contrast,according to various embodiments of the current invention, operating atmuch closer ranges means that it is practical to design the illuminationsubsystem, e.g., a laser, so as to provide sufficient illuminatingirradiance to provide a high SNR. For such an operating mode, thedominant noise term may be the shot noise of the return signal, whichgoes as the square root of the received signal. The focal plane arraymay then be selected to be one with high dynamic range (which may bedefined in terms of the maximum signal that may be measured divided bythe intrinsic noise levels of the array). Because the shot noise level,instead of the intrinsic noise level, is the limiting term, one usefulfeature of the focal plane array may include the presence of deep wells(corresponding to a high saturation level). For example, well depths of100,000 electrons or greater may provide an SNR of about 300 or greater,so long as the intrinsic noise levels are approximately 100 electrons orless. Additionally, whereas applications such as disclosed by Taboadamay require focal plane arrays configured to minimize intrinsic noise,such arrays may require special designs limiting the number of pixels orincreasing the cost, which may reduce the practical performance of thesystem.

3. System

FIG. 5 schematically illustrates selected components in athree-dimensional imaging system 500, according to some embodiments ofthe present invention. It should be appreciated that the functionalityof system 500 may alternatively be provided with other opticalarrangements, for example as described below. As illustrated in FIG. 5,system 500 includes illumination subsystem 510, sensor subsystem 520,and processor subsystem 540. Each of these subsystems will now bedescribed in greater detail.

A. Illumination Subsystem 510

Illumination subsystem 510 includes light source 511 for generating alight pulse, transmission (Tx) lens 512 for controlling the divergenceof the generated light pulse, and optional phase plate or otherbeamshaping element 513 for enhancing the spatial profile of the lightpulse. The positions of lens 512 and optional phase plate 513 mayalternatively be reversed. These elements may also be combined in asingle optic or set of optics. Illumination subsystem 510 is in operablecommunication with controller 541, which may control and/or monitor theemission of light pulses from light source 511, and which further maycontrol and/or monitor the divergence that transmission lens 512 impartson the generated light pulse.

As noted above, with reference to FIG. 1, the illumination subsystempreferably generates a light pulse having a smooth spatial profile, asmooth temporal profile, and a divergence of between, for example, 5 and40 degrees. The light pulse may be in any suitable portion of theelectromagnetic spectrum, for example, in the visible band (e.g.,400-700 nm) or in the near-infrared band (e.g., 700 nm-2500 nm).Generally, pulses generated in specific regions of the near-infraredband are considered to be more “eye-safe” than pulses of comparablepower in the visible band. Light source 511 is configured to generate alight pulse in the desired electromagnetic band, and lens 512 andoptional phase plate 513 are configured to provide that light pulse withthe desired divergence and optionally further to enhance the pulse'sspatial profile. In some embodiments, light source 511 is a laserproducing light pulses having at least 5 μJ energy, or at least 100 μJenergy, or at least 1 mJ energy, or at least 10 mJ energy. Such laserenergies may be relatively eye-safe because of the high divergence ofthe laser beam.

First, a brief description of some issues associated with previouslyknown lasers will be provided. Then, a description of a low-coherencelaser that may be used as light source 511 will be provided.

One of the unique features of a laser beam is its ability to be focusedto a small diameter, and, relatedly, to propagate for long distanceswithout appreciably changing in diameter. Since the invention of thelaser in the early 1960's, significant work has been done to improve theperformance of laser devices in these respects, particularly to be ableto focus the laser to the diffraction limit. Some of such efforts havefocused on increasing the spatial and temporal coherence of the laserbeam, for example, by limiting the number of spatial and temporal modesof the laser by carefully designing the laser cavity, providing cavitymirrors of optimum curvature, by placing small apertures at particularlocations within the laser cavity to inhibit lasing of higher ordermodes, and/or controlling aberration-inducing effects such as thermallensing. Other devices and techniques may also be used to improve thebeam characteristics.

A technique for improving the efficiency of a laser that outputs energyprimarily in the fundamental mode is to match the diameter of the gainvolume to the diameter of the laser cavity mode volume. The modediameter is determined by the radii of curvature of the cavity mirrorsand the separation of these mirrors. For stable resonator cavities, thisdiameter is typically small. This limits the total energy that may beextracted from the laser for each pulse because of gain saturationeffects. Unstable resonator designs may be used to increase theintracavity mode size for the fundamental spatial mode so that largergain volumes may be used while still only exciting the fundamentalspatial mode. However, high gain laser media are required to overcomethe high losses intrinsic in unstable cavities, and diffraction effectsfrom the cavity mirrors cause significant modulation in the outputspatial profile. Outside of a laser cavity, deformable mirrors and phasecorrectors may be used to correct aberrations that may reduce thefocusability of the laser beam.

The use of such techniques in laser design may cause trade-offs in othercharacteristics of the laser device. For example, design output power orenergy may be reduced during attempts to reduce the effects of thermaldistortions, gain saturation effects, the effects of higher ordertransverse modes, and the like. Design choices to improve the spatialcoherence of the beam, e.g., to eliminate higher order modes, may alsolead to the use of more expensive mirrors and optical designs. Suchdesign considerations may increase system cost and complexity.

However, there are many applications in fields such as laser imagingwhere the focusability of the laser beam is not important. Indeed,additional optical elements may be introduced to expand the laser beamto fill an area of interest. The spatial and temporal coherence of thelaser beam may, in such applications, cause “speckle,” in which thelaser beam interferes with itself, causing undesirable intensityvariations across the laser spot on the target. For some laser imagingapplications, it may be desirable to reduce the spatial and temporalcoherence of the laser beam, so that the laser instead functionsprimarily as a monochromatic, well-controlled, uniform “flashlight.” Thecriteria for producing a laser configured for such a low-coherenceapplication may be significantly different than those for adiffraction-limited beam. For example, a low-coherence laser may beconfigured to provide high output power or energy for a relatively lowcost, both for pulsed and continuous wave (CW) laser devices. Lowerspatial coherence may also reduce the focusability of the laser on theretina of the eye, thereby improving eye safety.

Referring again to FIG. 5, three-dimensional imaging system is onenon-limiting example of a wide field-of-view system in which reducedspatial and/or temporal coherence may be useful. Illumination subsystem510 may generate a laser pulse having a large divergence, e.g., between1 and 180, or between 1 and 90, or between 1 and 40, or between 2 and40, or between 5 and 40 degrees of divergence, and low spatial and/ortemporal coherence, whereas a diffraction-limited laser may have adivergence of only a fraction of a degree and a large amount of spatialand temporal coherence. The large divergence and lack of spatial and/ortemporal coherence may reduce the amount of intensity fluctuations inthe laser irradiance at the surfaces of objects being illuminated withthe laser beam. The smoother intensity profile of the laser beamgenerated by illumination subsystem 510 may improve the performance ofsensor subsystem 520.

FIG. 6A schematically illustrates one embodiment of a low-coherencelaser 600 suitable for use as light source 511 of FIG. 5. Laser 600includes seed laser 610, which generates light pulses, and optionallyfurther includes amplifier 620, which may include one or more stages foramplifying the intensity of the light pulses generated by seed laser610. Laser 600 may operate under the control of controller 541illustrated in FIG. 5. It should be noted that laser 600 mayalternatively be a standalone system (that is, not included in system500), in which case it may include its own laser controller.

Referring to FIG. 6A, seed laser 610 includes gain medium 631, first andsecond cavity mirrors 632, 633, diode or other pump 634, optionalQ-switch 635, and optional polarizer 636. Cavity mirror 633 preferablyis a high reflector, while cavity mirror 623 is partially transmissiveto allow laser light out of the laser and into optional amplifier 620 oronto the scene. At least one of cavity mirrors 632, 633 optionally maybe coated directly onto gain medium 631, obviating the need for aseparate optical component. Active Q-switch 635 and polarizer 636 may beconfigured to hold off lasing within the cavity until a desired time,e.g., until a time at which it is desired to obtain a laser pulse fromseed laser 610. Although many embodiments described herein pertain toseed laser 610 being configured to generate laser pulses, seed laser 610alternatively may be configured to generate a continuous-wave (CW) laserbeam.

In some embodiments, seed laser 610 preferably generates a laser pulseof 1 nanosecond or shorter, and including a sufficient number of spatialmodes to provide a substantially uniform spatial profile. The meaning of“substantially uniform” temporal and spatial profile is provided above.Additionally, the presence of many spatial modes may also increase thetotal number of longitudinal modes present in the laser beam. Forexample, as illustrated in FIGS. 6B-6C, the laser pulse generated byseed laser 610 preferably includes a sufficient number of spatial modes651, . . . 659 that when such spatial modes may interfere with oneanother, the result is a substantially smooth overall spatial profile650, as well as a sufficient number of temporal modes (which may berelated to the spatial modes) 661, . . . 669 that such temporal modesmay interfere with one another so as to provide a substantially smoothoverall temporal profile 660. In some embodiments, seed laser 610generates a laser pulse having at least 10 spatial modes, or at least 20spatial modes, or at least 30 spatial modes, or at least 40 spatialmodes, or at least 50 spatial modes, or at least 100 spatial modes,e.g., any number that may provide a smooth spatial profile. In someembodiments, seed laser 610 generates a laser pulse having at least 10temporal modes, or at least 20 temporal modes, or at least 30 temporalmodes, or at least 40 temporal modes, or at least 50 temporal modes, orat least 100 temporal modes, e.g., any number that may provide a smoothtemporal profile. In other embodiments, seed laser 610 includes only afew modes, e.g., between 2 and 10 spatial and/or temporal modes.

Referring again to FIG. 6A, gain medium 631 may be selected, based onthe desired operating wavelength of laser 600, from any of a variety ofgain media known in the art or yet to be discovered. For example, asdescribed in greater detail below, gain medium 631 may include alarge-core active fiber (fiber with active laser dopant in the core).Or, for example, gain medium 631 may include a solid-state material suchas Nd:YAG, Er:YAG, Cr:YAG, Ti:Sapphire, or Tm,Ho:YAG, among others.Alternatively, gain medium 631 may include a semiconductor material suchas InGaAs, and seed laser 611 is a pulsed diode laser that requires noseparate optical pump for exciting the gain medium.

Diode 634, or any other suitable pump for exciting gain medium 631, isconfigured to excite gain medium 631 so as to induce lasing within theresonant cavity bounded by mirrors 632, 633 and having length L. The lowspatial coherence of the laser beam is achieved by designing seed laser610 so as to support a large number of spatial modes within the resonantcavity. For example, the gain diameter D may be made significantlylarger than the fundamental mode diameter d. Higher order modes have alarger diameter than the fundamental mode, so the larger gain diameter Dsupports many spatial modes simultaneously. Additionally, oralternatively, the curvatures of mirrors 632, 633 may be chosen toreduce or minimize the difference in loss between the higher order modesand the fundamental modes. This may also be described as configuring thecavity so as to increase its Fresnel number. It is known that resonatorcavities using planar mirrors or nearly planar mirrors are lesseffective in discriminating higher order modes. As such, one or both ofmirrors 632, 633 may be planar, or nearly planar. For example, in oneembodiment mirror 632 (or 633) is planar, and mirror 633 (or 632) isconcave with a radius of curvature greater than 1 meter.

Additionally, or alternatively, the cavity length L, i.e., theseparation between mirrors 632, 633 may be decreased. The minimum cavitylength is the minimum distance that will contain all of the requiredcomponents within the resonator cavity. If the cavity is configured suchthat the single pass gain is made significantly higher than the lossesassociated with the higher-order spatial modes, for example, the singlepass gain is greater than 3, lasing may occur across the entire gaindiameter D and the beam exiting the laser resonator will have a spatialprofile that reflects the spatial profile of the gain distribution.Preferably, the beam will include a sufficient number of spatial modesthat the overall spatial intensity profile of the beam will besubstantially smooth. The relatively small separation L between mirrors632, 633 and the relatively large gain diameter D may enable seed laser610 to be fabricated compactly, with reduced complexity of couplingoptics for the pump source, and simplified mechanical design, which mayresult in enhanced stability. All of such aspects may result in a laserhaving lower cost and greater effectiveness for laser imagingapplications and devices as compared to single-mode or other traditionallaser designs.

In some embodiments, seed laser 601 is configured such that the spatialprofile of the gain distribution is approximately uniform in thedirection transverse to the optical axis of the laser resonator (thez-direction in FIG. 6A). Such a configuration may provide a laser pulsehaving a substantially flat spatial profile and containing numerousspatial modes. In other embodiments, seed laser 601 is configured suchthat the spatial profile of the gain distribution is adjusted toincrease the number of higher order modes in the laser beam. Forexample, if the fundamental mode is preferentially located near thecenter of the gain distribution, the gain profile may be adjusted toreduce the gain at the center, where the fundamental mode is located.Such an adjustment may be made, for example, by reducing thereflectivity of mirror 632 or 633 near the center of the cavity, or byproviding an additional optical element within the cavity that isconfigured to absorb a small amount of energy near the center of thecavity. Reducing the gain near the center of the cavity may decrease theamount of energy available to the fundamental mode and/or other lowerorder modes, and thereby increase the amount of energy available to thehigher order modes. The presence of many spatial modes may also increasethe total number of longitudinal modes present in the laser beam.

Additionally, or alternatively, an optic such as a phase plate,optionally may be included the cavity of seed laser 610. Such an opticmay decrease the discrimination between the spatial resonator modes, aswell as increase the coupling of energy transfer between modes as theenergy builds up within the resonator cavity. Such an optic may also beused to increase the loss associated with the fundamental mode. Such anoptic may be provided as a separate optical component, or may beprovided as a coating on one or both of mirrors 632, 633.

The temporal coherence of the beam may also be decreased by maximizingthe beam's spectral bandwidth. For example, some or all of theabove-noted techniques for increasing the number of spatial modes mayalso increase the bandwidth of the laser light. Or, for example,decreasing the pulse length τ_(p) may also increase the spectralbandwidth Δλ because the two quantities are related by the followingequation:

$\begin{matrix}{{\Delta\lambda} \geq \frac{\tau_{p}c}{K}} & (2)\end{matrix}$

where K is a constant of order unity that varies with the spectral andpulse temporal shape and c is the speed of light.

As noted above, seed laser 610 optionally also includes Q-switch 635 andpolarizer 636. The pulse length τ_(p) for an optimized laser pulse froma resonant cavity including a Q-switch may be described by:

$\begin{matrix}{{\tau_{p} = {\frac{2\; L}{\delta}\left( \frac{\ln \; z}{z\left( {1 - {a\left( {1 - {\ln \; a}} \right)}} \right)} \right)}},{where}} & (3) \\{{z = \frac{\ln \; G^{2}}{\delta}},{where}} & (4) \\{a = \frac{z - 1}{z\; \ln \; z}} & (5)\end{matrix}$

and where δ is the resonator loss and G is the single pass gain. Thisformula often is only an approximation of the operation of a Q-switchedlaser device, but it serves to illustrate some of the parameters thataffect the laser pulse length. As noted above, the pulse length of thelaser pulse generated by seed laser 610 is decreased by reducing theseparation L between mirrors 632, 633. In some embodiments, seed laser601 may be configured such that the separation L is sufficiently largethat the spectral spacing Δv=c/2L between the longitudinal cavity modesis less than the emission spectral bandwidth of the gain material. Inother words, the cavity length L is configured so as to be long enoughto support multiple longitudinal modes.

In other embodiments, the pulse length t may be decreased by decreasingthe reflectivity of mirror 632, and/or by increasing the single passgain in the resonator cavity, which may increase the number oflongitudinal and spatial cavity modes.

Although Q-switch 635 is described above as being active, alternativelyit may be of passive design, e.g., using a saturable absorber or othermaterial with variable transmission, and polarizer 636 may be omitted.The laser pulse length for such a configuration may be similar to thatdescribed above for an active Q-switch. In another embodiment (notillustrated), seed laser 610 is configured so as to have a cavity-dumpeddesign in which mirrors 632, 633 are both high reflectors, and seedlaser 610 further includes a fast optical switch configured to “dump”the laser pulse out of the cavity after the pulse reaches a sufficientpower. In yet another embodiment, seed laser 610 includes an active or apassive mode-locker that generates a sequence of pulses. The sequence ofpulses may all be used to illuminate the scene, or a single pulse may beselected, e.g., using a fast optical switch. As noted above, however,laser 600 may be used in any other suitable system, or as a standalonedevice, and is not limited to use with the three-dimensional imagingsystems provided herein. The pulse generated by seed laser 610optionally may be amplified via amplifier 620. Amplifier 620 may haveany suitable design and may be selected from a variety of amplifiersknown in the art, or yet to be invented.

Some embodiments use a fiber waveguide or photonic band gap material forgain medium 631. Some fiber lasers or fiber amplifiers are limited toapproximately 1 MW peak power because of the risk of nonlinear damageeffects. Fiber cores that transport the laser light may be 6-20 μm indiameter, with traditional designs focused on limiting the spatial modecontent of the beam. The maximum energy typically achievable with fiberlasers is limited to about 1 mJ or less because of the onset ofnonlinear effects at high intensities within the fiber core. In oneembodiment, gain medium 631 includes a fiber having a core that is 200μm in diameter, with a length and coupling chosen to improve thecoupling between all of the guided modes and filling the core. Such amedium may be up to 100 times larger than a typical fiber core, whichmay allow the peak power from the fiber laser to be up to 100 MW withoutthe risk of nonlinear damage effects or adverse distortion effects.Other embodiments use other core diameters that increase the allowablepeak power in the fiber relative to typical fibers, for example, between50 and 500 μm, or between 100 and 400 μm, or between 150 and 250 μm. Insuch fiber-based embodiments, the relatively large core diameter mayalso provide a greater number of spatial modes and decrease the spatialcoherence of the output laser beam.

Such fiber-based embodiments may include both fiber-based resonators aswell as pulsed laser designs in which the laser pulse is produced by alaser oscillator that may or may not be fiber-based. In the latter case,the laser pulse may be amplified in one or more amplifier stages 620with couplers and isolators between the stages. Each of these stages mayinclude an active core fiber (fiber with an active laser dopant in thecore) and the core initially may be small, increasing with increasedamplifier energy, or the core may be large in all of the amplifierstages 620. In a different embodiment, laser 600 is based on fibertechnology, which may enable higher overall gain to be obtained from arelatively low-gain gain medium 630, while providing robust operationbased on mature 1500 nanometer fiber technology. For example, in oneembodiment seed laser 610 may include a fiber having a diameter of 200μm and may generate pulses having a wavelength of 1500 nm, a pulseduration of 500 picoseconds, and an energy of approximately 1 nJ.Amplifier 620 may include a three-stage fiber-based amplifier to amplifythe pulse to an energy of 0.5 mJ, followed by a very large coreamplifier to amplify the pulse to an energy of 40 mJ or greater. Inanother embodiment, seed laser 610 includes a pulsed diode and amplifier620 may include a fiber-based amplifier.

In some embodiments, low coherence laser 600 generates pulses having awavelength of 1400 nm or greater, an energy of 40 mJ or greater, and apulse duration of less than 500 picoseconds. There are several gainmedia 631 that emit in this spectral region, including Er:YAG, Cr:YAG,and Tm,Ho:YAG. For example, the material Er:YAG has been used to producepulses at 1617 nm having 1 nanosecond pulse lengths and 0.6 mJ output at10 kHz pulse repetition frequencies. However, Er:YAG offers relativelylow gain, making it difficult to scale to higher pulse energies for evenshorter pulse lengths, e.g., 500 picoseconds or shorter. The otherlisted materials may have similar constraints. As noted above, laser 600may include amplifier 620 to amplify the seed pulse energy generated byseed laser 610. For example, amplifier 620 may include an opticalparametric amplifier (OPA) to amplify light in this spectral region(1400 nm or greater) using an Nd:YAG pump. However, OPAs are typically30-40% efficient, and so in some embodiments amplifier 620 is configuredto generate pump pulses of 100 mJ or greater to amplify the pulse energygenerated by seed laser 610. Those of ordinary skill in the art mayreadily devise other ways of amplifying the energy generated by seedlaser 610.

Referring again to FIG. 5, transmission (Tx) lens 512 may increase thedivergence of the light pulse generated by light source 511 (e.g., lowcoherence laser 600 of FIG. 6A, or any other suitable laser, includingin one embodiment a high coherence laser). For example, although thelight pulse from light source 511 may in some embodiments be relativelyhighly divergent compared to previously known lasers because the pulsecontains many spatially and temporally incoherent modes, the pulse'sdivergence may in some circumstances still remain well below 1 degree.Lens 512 may be configured to increase the divergence of the light pulseto between 5 and 40 degrees, depending on the distance of the scene fromsystem 500 and the portion thereof to be imaged. Lens 512 may include asingle lens, or may include a compound lens, or may include a pluralityof lenses or mirrors, that is/are configured to increase the divergenceof the pulse to the desired degree, e.g., to between 1 and 180 degrees,or 1 and 120 degrees, or 1 and 90 degrees, or 2 and 90 degrees, or 2 and40 degrees, 5 and 40 degrees, or between 5 and 30 degrees, or between 5and 20 degrees, or between 5 and 10 degrees, or between 10 and 40degrees, or between 20 and 40 degrees, or between 30 and 40 degrees, orbetween 10 and 30 degrees, for example. Divergences larger or smallermay also be used. In some embodiments, transmission lens 512 may beadjustable, so that a user may vary the divergence of the laser pulse tosuit the particular situation. Such an adjustment may be manual (similarto the manual adjustment of a “zoom” lens), or may be automated. Forexample, controller 541 may be operably connected to transmission lens512 so as to automatically control the degree of divergence that lens512 imparts to the laser pulse. Such automatic control may be responsiveto user input, or may be part of an automated scene-imaging sequence, asdescribed in greater detail below.

Illumination subsystem 510 optionally may further include phase plate513, which is configured to further smooth the spatial profile of thelight pulse generated by light source 511.

It should be noted that although illumination subsystem 510 includeslight source 511, which is substantially monochromatic, it optionallymay include additional types of light sources. For example, illuminationsubsystem 510 may include a white light source for illuminating thescene with white light. Or, for example, illumination subsystem 510 mayinclude other substantially monochromatic light sources in spectralregions different from that emitted by light source 511. For example,where light source 511 generates laser pulses in one particular portionof the visible spectrum, such as in the green region, e.g., 532 nm, suchpulses may cast that hue over the scene. In some circumstances, such asthe filming of a movie, this may be undesirable. Illumination subsystem510 may include one or more additional light sources that generate lightthat, when combined with the light from light source 511, result in theappearance of white light. For example, where light source 511 generatesgreen laser pulses (e.g., 532 nm), illumination subsystem 510 optionallymay further include diodes or lasers or other light sources that emitwavelengths in the red and blue regions, e.g., 620 nm and 470 nm, that,combined with the green laser pulses to produce an illumination thatmaintains the desired scene illumination characteristics.

B. Sensor Subsystem 520

Still referring to FIG. 5, system 500 further includes sensor subsystem520, which receives portions of the light pulse, generated byillumination subsystem 510, that are reflected and/or scattered byobjects in the scene. Optionally, sensor subsystem 520 also receivesvisible light from the scene, which light may be from ambient sourcesand/or may be produced by a separate light source in illuminationsubsystem 510. In the embodiment illustrated in FIG. 5, sensor subsystemincludes receiving (Rx) lens 521, band-pass filter (BPF) 522, polarizer(Pol.) 523, modulator 524, optional compensator (Cp.) 525, imaging lens526, polarizing beamsplitter 527, and first and second FPAs 528, 529.Sensor subsystem optionally further includes white light imagingsubsystem 530, which includes dichroic beamsplitter 531 and FPA 532.Sensor subsystem 520 is in operable communication with controller 541,which may monitor and/or control the operation of different componentsof the sensor subsystem, such as receiving lens 521, modulator 524,imaging lens 526, FPAs 528, 529, and optional FPA 532.

Receiving lens 521 collects light from the scene. As discussed abovewith reference to FIG. 1, the scene may scatter and/or reflect light ina variety of directions other than back toward the three-dimensionalimaging system. Some of such light was generated by illuminationsubsystem 510, while other of such light may be white light or light ina different wavelength range, which may or may not have been generatedby illumination subsystem 510. The amount of light collected isproportional to the area of the receiving aperture, e.g., isproportional to the area of receiving lens 521.

To enhance the amount of light collected by sensor subsystem 520, thusincreasing the amount of information that ultimately may be contained ineach three-dimensional image, receiving lens 521 is constructed toreceive as much light as practicable for the given application. Forexample, for some applications in which the imaging system is designedto be lightweight and hand-held, with modest resolution requirements,receiving lens 521 may, for example, have a diameter of 1 to 4 inches,or 2 to 3 inches, or for example, about 2 inches, or smaller. Forapplications in which the imaging system is instead designed to providehigh-resolution images for commercial purposes, receiving lens 521 maybe made as large as practicably feasible, for example, having a diameterof 2 to 6 inches, or 2 to 4 inches, or 1 to 3 inches, or, for example, 4inches. The various optical components of sensor subsystem 520preferably are configured so as to avoid clipping or vignetting thelight collected by receiving lens 521 using techniques known in opticaldesign. Additionally, receiving lens 521 and the other opticalcomponents or coatings preferably also have a wide angular acceptance,e.g., of between 1 and 180 degrees, or between 1 and 120 degrees, orbetween 1 and 90 degrees, or between 2 and 40 degrees, or between 5 and40 degrees.

Receiving lens 521 may include a single lens, or may include a compoundlens, or may include a plurality of lenses or mirrors, that is/areconfigured to collect light from the scene and to image the collectedlight into an image plane at a defined position within sensor subsystem520. Receiving lens 521 preferably is configured to reduce or inhibitthe introduction of spherical and chromatic aberrations onto thecollected light. In some embodiments, receiving lens 521 may beadjustable, so that a user may choose to adjust the position of theobject plane of lens 521, or the distance at which the scene is imagedto the defined plan within sensor subsystem 520. In some embodiments,receiving lens 521 can be adjusted to change the angular FOV. Such anadjustment may be manual (similar to the manual adjustment of a “zoom”lens), or may be automated. For example, controller 541 may be operablyconnected to receiving lens 521 so as to automatically control theposition of the object plane of lens 521 or angular FOV of lens 521. Insome embodiments, these adjustments may be performed in part based onthe beam divergence imparted by transmission lens 512 (which also may becontrolled by controller 541). Such automatic control may be responsiveto user input, or may be part of an automated scene-imaging sequence, asdescribed in greater detail below.

In the embodiment illustrated in FIG. 5, sensor subsystem 520 includesvisible imaging subsystem 530, so the light collected by receiving lens521 is imaged at two image planes. Specifically, the collected lightpasses through dichroic beamsplitter 531, which is configured toredirect at least a portion of the collected visible light onto FPA 532,which is positioned in the image plane of receiving lens 521. FPA 532 isconfigured to record a color or grey-scale image of the scene based onthe visible light it receives, e.g., using previously known hardware andtechniques. In some embodiments, FPA 532 is substantially identical tofirst and second FPAs 528, 529, and is configured so that the visiblelight image it records is registered with the images that the first andsecond FPAs record. FPA 532 is in operable communication with controller541, which obtains the image from FPA 532 and provides the obtainedimage to storage 542 for storage, which may be accessed by imageconstructor 543 to perform further processing, described in greaterdetail below. It should be appreciated that visible imaging subsystem530 alternatively may be configured to obtain an image based on anyother range of light, for example, any suitable broadband or multibandrange(s) of light.

Light that dichroic beamsplitter 531 does not redirect to FPA 532 isinstead transmitted to band-pass filter 522, which is configured toblock light at wavelengths other than those generated by illuminationsubsystem 510 (e.g., has a bandwidth of ±5 nm, or ±10 nm, or ±25 nm), sothat the remainder of sensor subsystem 520 receives substantially onlythe laser pulse portions generated by illumination subsystem 510 thatthe scene reflects or scatters back towards system 500 (e.g., pulseportions 127, 128, 129 illustrated in FIG. 1). The light transmittedthrough band-pass filter 522 is then transmitted through polarizer 523,which eliminates light of polarization other than a desiredpolarization, e.g., so that the light transmitted therethrough issubstantially all H-polarized, or substantially all V-polarized (orright handed circularly polarized, or left handed circularly polarized).Polarizer 523 may be, for example, a sheet polarizer, or a polarizingbeamsplitter, and preferably is relatively insensitive to angle. Thelight transmitted through polarizer 523 is then transmitted throughmodulator 524, which is positioned at the other image plane of receivinglens 521. The functionality of modulator 524 is described in greaterdetail below. In some embodiments, the image plane of receiving lens 521is at a location in sensor subsystem 520 other than in modulator 524.

Modulator 524 optionally may be followed by compensator 525, which maycorrect phase errors that modulator 524 may impose on the beam due tovariations in the beam angle, thus further enhancing the acceptanceangle of modulator 524. Compensator 525 may include a material havingthe opposite birefringence of the material in modulator 524. Forexample, where modulator 524 includes potassium dihydrogen phosophate(KDP), compensator 525 may include magnesium fluoride (MgF₂) which hasthe opposite birefringence of KDP and is commercially available. Othermaterials may be suitable for use in compensator 525, depending on thecharacteristics of the material used in modulator 524, such as if themodulator material is potassium dideuterium phosphate (KD*P),compensator materials may be rutile, yttrium lithium fluoride (YLF),urea, or yttrium orthovanadate (YVO₄), among others. Additionally, thethickness of compensator 525 may be selected to provide an appropriatecontrast ratio over the acceptance angle of the system. In oneillustrative embodiment, compensator 525 includes a crystal of MgF₂having a length between 8.78 mm and 8.82 mm for a modulator of KD*P of 3mm length. For other modulator designs, such as modulator materials thatare oriented such that the crystal axis is orthogonal to the opticalaxis, the compensator may be a second modulator with the crystal axisrotated 90 degrees about the optic axis.

Following transmission through and modulation by modulator 524 andoptional compensator 525, imaging lens 526 images the modulated lightonto first and second FPAs 528, 529. Specifically, polarizingbeamsplitter 527 separates the orthogonal polarization components of themodulated beam (e.g., the H- and V-polarization components, or left- orright-handed circularly polarized components), which it then redirectsor transmits, respectively, to first and second FPAs 528, 529, which arepositioned in the image plane of imaging lens 526. Imaging lens 526 mayinclude a single lens, a compound lens, or a plurality of lenses. Insome embodiments, two imaging lens 526 may be placed after thepolarizing beamsplitter 527, with one each in front of FPAs 528, 529.First and second FPAs 528, 529 record images of the modulated lightimaged upon them, and are in operable communication with controller 541,which obtains the recorded images and provides them to storage 542 forstorage and further processing by image constructor 543.

A description of various embodiments of modulator 524 and FPAs 528, 529will now be provided. A description of the calculation of objectpositions and shapes within the scene will be provided further belowwith reference to processor subsystem 540.

Modulator

As noted above with reference to FIG. 1, a modulator may be used to varythe polarization of the laser pulse portions reflected from the scene,allowing for the ranges and shapes of objects in the scene to becalculated with high precision. A Pockels cell or a Kerr cell may insome embodiments be used to perform such a modulation. However,previously known Pockets cells typically have relatively small apertures(e.g., 1 cm or smaller) and small acceptance angles (e.g., less than 1degree) and operate at relatively high voltages, which may make themundesirable for use in imaging systems. Additionally, the angular extentof the reflected light received by the modulator may be magnified by theinverse of the magnification of the receiving optical elements. As such,it may be desirable to use a modulator having a wider acceptance angle,a wider aperture, and a lower operating voltage. For example, in thethree-dimensional imaging system illustrated in FIG. 5, the lightcaptured by receiving (Rx) lens 521 may have angles varying between 5and 40 degrees and an aperture of 2-4 inches, for example, which apreviously known Pockels cell may not be configured to properlymodulate. Thus, it may be desirable to provide a polarization modulatorhaving a large aperture, a low operating voltage, and a large acceptanceangle, e.g., greater than 5 degrees, for example, between 5 and 40degrees, while providing a high contrast ratio, e.g., greater than300:1, or greater than 500:1.

For embodiments in which the modulator is a Pockels cell, there areknown techniques for increasing the angular acceptance bandwidth of aPockels cell. These may be used in various embodiments of the invention.For example, in one embodiment, the Pockels cell may be made thin byusing transparent electrodes. Decreasing the length increases theangular acceptance. Similarly, the modulator aperture may be increasedby using transparent electrodes. In one illustrative example, modulator524 is a longitudinal Pockels cell including a slab of potassiumdideuterium phosphate (KD*P) having a thickness of less than 5 mm withtransparent or semi-transparent electrodes disposed thereon or onprotective windows placed proximate to the KIM surfaces, e.g., a coatingof indium tin oxide (ITO), a conductive grid having a spacing selectedto match the pixel spacing of FPAs 528, 529 to reduce diffractionlosses, or any suitable combination of transparent film and metallicfeatures.

Pockels cell materials have birefringence (different values of therefractive index for light polarized along different axes of the crystalstructure) which further restricts the angular acceptance. However, forPockels cell designs known as transverse cells, manufacturers havecarefully matched the thickness of two identical cells, rotating thecells 90 degrees about the propagation axis. One cell then cancels outthe contribution of the other. For some materials and orientations, itmay be necessary to use four cells. This also may make the cellsrelatively insensitive to effects caused by temperature changes. Such atechnique may not work for longitudinal Pockels cells, but in this case,additional material is added. The material has birefringence of oppositesign and the thickness is carefully matched. For example, potassiumdihydrogen phosphate (KD*P) is a common material for longitudinal cellsand is negatively birefringent. Positively birefringent materials arealso available, such as MgF₂. These techniques may allow for a highangular acceptance for a Pockels cell modulator.

One embodiment of a modulator having a wide aperture and largeacceptance angle is illustrated in FIG. 7A. Pockels assembly 700includes stack of transverse Pockels cells 721, . . . 728 arranged bothoptically in parallel and electrically in parallel or in series, andvoltage source 750 coupled thereto via conductors 751, 752. Voltagesource 750 may be included in processor subsystem 540 of FIG. 5, or maybe included in sensor subsystem 520 and controlled by controller 541.Pockels cells 721, . . . 728 are secured together using any appropriatemeans, such as an adhesive between the Pockels cells, or a housingsurrounding the cells so as to secure them together, or otherwiseappropriately secured, for example via the electrodes, as describedbelow. Although the illustrated embodiment includes eight transversePockels cells 721, . . . 728 (cells 722-724 being omitted for clarity),any suitable number of transverse Pockels cells may be used, e.g.,between 5 and 10,000 transverse Pockels cells, or, e.g., between 10 and500 transverse Pockels cells, or, e.g., between 20 and 200 transversePockels cells, or, e.g., between 50 and 100 transverse Pockels cells. Insome embodiments, Pockels assembly 700 is constructed so as to provide acontrast ratio of, for example, greater than 300:1, or even greater than500:1.

Transverse Pockets cell 721 includes a thin slab 740 of electro-opticmaterial, and first and second electrodes 741, 742 are disposed onopposing major surfaces of slab 740. Slab 740 may have a thickness of,for example, less than 1 mm. In particular, it may be preferable forslab 740 to have a thickness of less than 100 μM, or of less than 50 μm,for example, between 100 and 10 μm, or between 80 μm and 30 μm, orbetween 60 μm and 40 μm, or about 50 μm. Slab 740 may be made of anysuitable material, including but not limited to potassium dihydrogenphosophate (KDP), potassium dideuterium phosphate (KD*P), lithiumniobate (LN), periodically poled lithium niobate, lithium tantalate,rubidium titanyl phosphate (RTP), beta-barium borate (BBO), andisomorphs of these crystalline materials. An isomorph has a similarmaterial and stoichiometric structure, but different elements. Theparticular dimensions and configuration of the elements of Pockelsassembly 700 may be selected based on the optical transmissioncharacteristics, electro-optic coefficients, refractive index,birefringence, and physical properties of the material selected for usein slab 740. Additionally, the edges of slab 740 may be polished toavoid distorting light propagating therethrough, and/or coated to reducereflections.

In Pockels assembly 700, the first electrodes 741 of each of Pockelscell 721, . . . 728 are connected in parallel to one another and to afirst conductor 751 coupled to voltage source 750, while the secondelectrodes 742 of each Pockels cell 721, . . . 728 are connected inparallel to one another and to a second conductor 752 coupled to voltagesource 750. Voltage source 750 applies an appropriately varying voltagepotential across first conductor 751 and second conductor 752, so as tovary the birefringence of each slab 740 as a function of time. Asindicated previously in equation (1), the required half-wave voltage fora transverse Pockels cell is proportional to the thickness. Since theaperture is divided into N cells, the thickness of each being 1/Nth thatof the combined aperture, the half-wave voltage that would be requiredto induce a relative it phase delay in orthogonal fields for a singlecrystal, expressed by equation (1) above, may be divided by N, thenumber of transverse Pockels cells 721, . . . 728 in Pockels assembly700. Thus, instead of a half-wave voltage of several hundreds orthousands of volts as required for previously known Pockels cells, whichmay require cumbersome high-voltage drivers, Pockels assembly 700 may becharacterized a half-wave voltage on the order of tens of volts, or evenless than ten volts, improving the practicality of incorporating it intoa commercial system.

First and second electrodes 741, 742 may include any suitable conductor,e.g., a metal such as gold, aluminum, copper, or solder, or a conductivepolymer, or a transparent conductor such as indium tin oxide (ITO),fluorine doped tin oxide (FTO), or doped zinc oxide. In one illustrativeembodiment, first and second electrodes 741, 742 are transparentelectrodes having approximately the same refractive index as slab 740.Electrodes 741, 742 may be disposed on opposing major surfaces of slab740 using any suitable method, e.g., with sputtering, electroplating,evaporation, spin-coating, and the like. Electrodes 741, 742 may alsoperform the function of securing Pockels cells 721, . . . 728 together.For example, electrodes 741, 742 may function as solder or braze thatsecures Pockels cells 721, . . . 728 to one another. One or more ofelectrodes 741, 742 optionally may also include an insulative cap toinhibit shorting between electrode 742 of one Pockels cell (e.g.,Pockels cell 725) and electrode 741 of another Pockels cell (e.g.,Pockels cell 726).

The optic axis of slab 740 is oriented in the z-direction, which isparallel to incident light 790, and the slab is oriented at a definedangle in the x- and y-directions relative to the polarization ofpolarizer 523 illustrated in FIG. 5. In the illustrated embodiment, slab740 is oriented parallel to the x-direction, corresponding to ahorizontal (H) polarization, although other arrangements are envisioned,depending on the particular arrangement and material used. The crystalaxes of the electro-optic material of slab 740 may be oriented in anysuitable direction. For example, the z-axis of the electro-opticmaterial may be parallel to, or may be orthogonal to, the propagationdirection of incident light 790, which in FIG. 7A is in the z-direction.Or, for example, the y-axis of the electro-optic material may beparallel to the propagation direction of incident light 790, or thex-axis of the electro-optic material may be parallel to the propagationdirection of incident light 790.

Pockels assembly 700 includes a sufficient number N of Pockels cells721, . . . 728 to provide a desired clear aperture D in the x-directionfor use in the desired application, e.g., for use in system 500illustrated in FIG. 5. Specifically, the minimum number N of Pockelscells is approximately equal to the desired clear aperture D, divided bythe thickness d of each Pockels cell (assuming all Pockels cells are thesame thickness), i.e., N=D/d. In many circumstances, the thickness ofelectrodes 741, 742 (which are not drawn to scale in FIG. 7A) isnegligible compared to the thickness of slab 740, in which case d may beapproximately equal to the thickness of slab 740. Each transversePockels cell 721, . . . 728 is also configured to have a lateraldimension at least as large as the desired clear aperture D.

As incident light 790 propagates through Pockels assembly 700, differentportions of that light enter different Pockels cells 721, . . . 728.Within each Pockels cell, the light propagating therethrough repeatedlyreflects off of the major surfaces of that cell, and experiencesinterference with itself. The phase of the light propagating through thesheets can be reconstructed, and thus the image at the entrance of thePockels cell, at periodic planes along the propagation direction. Thiseffect is known as the Talbot effect. The planes at which the phase andimage are reconstructed are known as Talbot imaging planes. Preferably,the Pockels cells 721, . . . 728 have a length L in the z-direction thatcorresponds to a Talbot imaging plane, so that the light incident toPockels assembly 700 will be re-imaged following propagation through theentirety of Pockels assembly 700. As such, the length L of transversePockels cells 721, . . . 728 is preferably approximately equal to:

$\begin{matrix}{L = {m\frac{4\; d^{2}n}{\lambda}}} & (6)\end{matrix}$

where m is an integer, d is the thickness of the Pockels cell, n is therefractive index of slab 740, and λ is the wavelength of the incidentlight. Additional image planes may also occur at ¼ multiples of thelength L in equation (6), but of inverted symmetry and/or greatersensitivity to characteristics of the incident light. The extendedsurfaces on which the electrodes are disposed may be polished in orderto reduce any phase randomization from scattering. The Talbot effectitself is insensitive to angle; however surface losses at the electrodeinterface may create a practical limitation to the angular acceptance ofassembly 700. In some embodiments, an additional layer or multiplelayers of optical coatings may be added to minimize any absorptive orrefractive losses at the interfaces between the slab 740 and theelectrodes 741, 742. Note also that in embodiments in which electrodes741, 742 are substantially transparent and have the same, orapproximately the same, refractive index as slab 740, the Talbot effectmay be reduced, or even vanish, because reflections between adjacenttransverse Pockels cells may be reduced, or even vanish. In such anembodiment, the length L of Pockels assembly 700 may be set to anyappropriate length (not necessarily dictated by equation (6)), as Talbotplanes may not necessarily occur.

In one embodiment, the incident laser light is centered at 1064 nm, m isequal to 1, the material is lithium niobate having a refractive index nof 2.237, and d is 0.05 mm, for which L is approximately equal to 2.1cm. In another embodiment, the thickness of the lithium niobate materialis 0.025 mm, for which L is approximately 0.53 cm. The aspect ratio ofthe material thickness to length decreases within decreasing thickness,which may be advantageous for manufacturability. The thickness andlength of the individual Pockels cells slabs 740 can be adjustedaccording to equation (6) to enhance overall performance.

In one embodiment, slab 740 comprises a crystal of lithium niobate thatis cut and polished such that incident light propagates parallel to thez-axis of the crystal and the first and second electrodes 741, 742 arethin layers of a metallic conductor, such as copper, disposed on themajor surfaces of slab 740, which are normal to the x-axis of thecrystal. In this embodiment, the x- and z-axes of the crystal areparallel to the x- and z-directions of the system, as defined in FIG.7A. For such a crystal, the half-wave voltage V_(1/2) is given by:

$\begin{matrix}{V_{\frac{1}{2}} = \frac{\lambda \; d}{2\; r_{22}n_{0}^{3}L}} & (7)\end{matrix}$

where r₂₂ is the electrooptic tensor element for lithium niobate, andn_(o) is the ordinary refractive index of lithium niobate. For a slabthickness of 0.05 mm and a central laser wavelength of 1064 nm and anordinary refractive index of 2.237, the half-wave voltage for Pockelsassembly 700 is approximately 21 V for r₂₂=5.61 pm/V.

Alternatively, periodically poled lithium niobate (PPLN) may be used asthe material in slabs 740. Chen et al. (Optics Letters, Vol. 28, No. 16,Aug. 15, 2003, pages 1460-1462, the entire contents of which areincorporated herein by reference) studied the response of a singletransverse Pockels cell including a PPLN slab of thickness of 1 mm andlength 13 mm, and reports a half-wave voltage of 280V. Because thisvalue may scale with thickness and length, it may be reasonably assumedthat for slab a thickness of 0.05 mm and a central laser wavelength of1064 nm, the half-wave voltage for a Pockels assembly 700 would beapproximately 9 V.

Alternatively as illustrated in FIG. 7B, Pockels assembly 700′ includestransverse Pockets cell 721′, . . . 728′, each of which includes a slab740′ having a crystal of lithium niobate that is cut and polished suchthat incident light 790′ propagates parallel to the x-axis of thecrystal. The first and second electrodes 741′, 742′ are disposed on themajor surfaces of slab 740′, which are normal to the z-axis of thecrystal. In this embodiment, the x- and z-axes of the crystal arerespectively parallel to the z- and x-directions defined in FIG. 7B. Anadditional phase for off-axis rays because of the natural birefringenceoptionally may be compensated for by providing a second, identicalPockets assembly 700″ which is rotated 90 degrees in the x-directionfrom assembly 700′. In this case, the required half-wave voltage of thetwo assemblies is approximately half that required for a singleassembly, e.g., assembly 700 in FIG. 7A.

FIG. 7C illustrates another alternative Pockels assembly 701 in whichthe first electrodes 741″ of adjacent Pockels cells are arranged so asto be disposed adjacent to one another and connected in parallel to oneanother and to a conductor 751″ coupled to voltage source 750″. Forexample, first electrode 741″ of cell 722″ is adjacent to and coupled tofirst electrode of cell 723″. The second electrodes 742″ of adjacentPockels cells are also arranged so as to be disposed adjacent to oneanother and connected in parallel to one another and to a conductor 752″coupled to voltage source 750″. For example, second electrode 742″ ofcell 721″ is adjacent to and coupled to second electrode 742″ of cell722″. An arrangement such as illustrated in FIG. 7C may obviate the needto provide an insulative cap on the electrodes, because the upper orlower electrode of adjacent Pockels cells are intentionally placed inelectrical contact with the lower or upper electrode of their neighbor.Indeed, in some embodiments only a single electrode need providedbetween each slab (that is, electrodes 742″, 742″ of Pockels cells 721″and 722″ may be combined to form a single electrodes).

It should be clear that Pockels assemblies 700, 700′, and 700″illustrated in FIGS. 7A-7B are not limited to use in three-dimensionalimaging systems, such as system 500 illustrated in FIG. 5. Instead,Pockels assembly 600 may be used in any appropriate system that wouldbenefit from a modulator having a large clear aperture, a low operatingvoltage, and/or a large acceptance angle.

Although system 500 of FIG. 5 is described as including a Pockelscell-based modulator, such as modulator 700 of FIG. 7A, other types ofmodulators may be used to encode the TOFs of reflected/scattered pulseportions from the scene as an intensity modulation on an FPA. Such anembodiment may not directly modulate the light, but instead may modulatethe amplitude of the signal generated by the photoelectrons measured bythe circuits of the FPAs. For example, in one alternative embodiment,polarizer 523, modulator 524, and compensator 525 are omitted, and thegain of the pixels of FPA 529 is modulated as a function of time,whereas the gain of the pixels of FPA 528 are not modulated as afunction of time. In this embodiment, the polarizing beamsplitter 527would be replaced by a nonpolarizing beamsplitter. An FPA includes anarray of photosensitive sites (referred to as pixels) with accompanyingcircuitry to measure the total charge created by incident photons. Someof the circuitry is configured to amplify the signal generated byphotoelectrons in the pixel so as to produce gain (the fraction of themeasured current to the number of photoelectrons generated). In thisembodiment, such circuitry may be configured to vary the gaincharacteristics of the array of FPA 529, and/or of individual pixels inthe array of FPA 529, over a time window of interest, e.g., 10 ns, toproduce a temporally dependent modulation in the electrical signalassociated with each pixel.

Such a temporally dependent modulation may be used to determine the TOFof a laser pulse portion reflected or scattered from a scene.Specifically, a non-modulated signal obtained using FPA 528 may be usedas a normalization image, against which the modulated image obtainedusing FPA 529 may be normalized. Alternatively, a non-modulated imagemay be obtained using FPA 529 by turning off any modulation for oneframe at some interval, which image may be used as a normalizationimage, against which the modulated image obtained using FPA 529 duringthe other frames may be normalized; in such an embodiment, beamsplitter527 and FPA 528 may be omitted. In such an embodiment, it is preferablethat objects in the scene do not significantly move between the time thenormalization image is acquired and the time the modulated image isacquired or the amount of light received by receiving lens 521 does notchange significantly; the frame rate of the FPA optionally may beadjusted to reduce the chance of such movement. The intensity of eachnormalized pixel represents the TOF of the pulse portionsreflected/scattered by the objects in the scene, and thus the distanceand shape of those objects. Although there is no absolute reference forthe intensity at each pixel, a frame at some periodic frequency during aseries of frames could be processed without modulation (e.g., the gainfor all pixels set to the maximum value being used). Such a frameprovides the absolute amplitude reference, provided that the reflectedsignal does not change significantly between reference frames.

Alternatively, instead of temporally modulating the gain of each pixel,the amount of light received by each pixel may be temporally modulatedby providing a polarization rotator, coupled to a thin polarizer, infront of each pixel. The polarization rotators may be individuallyaddressable, or may be collectively controlled so as to approximatelyuniformly vary the amount of light received by the pixels. Thenormalization image may be obtained, for example, analogously to asdescribed above for gain modulation. In another embodiment, thepolarization rotator may be omitted and a temporally variable attenuatorprovided instead. In general, a transducer may be used to vary theamount of photoelectrons that are produced by a pixel of the FPA in acontrolled function over 0.1-100 ns. In one embodiment, the transduceracts uniformly on all pixels of the FPA so that only one drive waveformis needed.

In another alternative embodiment, modulator 524 of system 500illustrated in FIG. 5 includes an electro-optic Bragg deflector, andcompensator 525 and beamsplitter 527 are omitted. FPA 528 is positionedto receive one diffraction order from the electro-optic Bragg deflector,and FPA 529 is positioned to receive the zero (or undiffracted beam)diffraction order from the electro-optic Bragg deflector. In someembodiments, the two Bragg orders will be incident on different areas ofthe same FPA 529. A temporally modulated control signal is applied tothe electro-optic Bragg deflector, so as to vary the intensity in thediffraction orders received by FPA 528 and 529 over a time window ofinterest, e.g., 10 ns. The images received and subsequent processing maybe substantially similar to those modulated by the Pockels assembly. Inone embodiment, only FPA 528 (or 529) receives a modulated signal, andFPA 529 (or 528) receives a non-modulated signal against which themodulated signal may be normalized.

In yet another alternative embodiment, modulator 524 of system 500includes an etalon, such as a temporally modulable Fabry-Perotinterferometer having opposing reflective surfaces. Polarizer 523,modulator 524, compensator 525, and beamsplitter 527 may be omitted. Thetransmission of an etalon for monochromatic light is based on thefinesse of the etalon and the spacing between the reflective surfaces;thus, by varying the distance between the surfaces as a function oftime, the intensity of light transmitted by the etalon to FPA 529 mayvary depending on the TOF of the light. In one embodiment, the etalon issolid, with the distance between the reflectors being controllablyvariable as a function of time using, for example, piezoelectrictransducers to compress or stretch the material. FPA 528 may beconfigured so as to receive non-modulated light, which may be used toobtain a normalization image against which the modulated image from FPA529 may be normalized.

FPAs

In the embodiment illustrated in FIG. 5, first and second FPAs 528, 529are positioned in the focal plane of imaging lens 526, and respectivelyreceive light of orthogonal polarizations. For example, polarizingbeamsplitter 527 may direct light of H-polarization onto FPA 528, andmay transmit light of V-polarization onto FPA 529. FPA 528 obtains afirst image based on a first polarization component, and FPA 529 obtainsa second image based on the second polarization component. FPAs 528, 529provide the first and second images to processor subsystem 540, e.g., tocontroller 541, for storage and further processing, as described ingreater detail herein. Preferably, FPAs 528, 529 are registered with oneanother. Such registration may be performed mechanically, or may beperformed electronically (e.g., by image constructor 543).

In some embodiments, FPAs 528, 529 are off-the-shelf CCD or CMOS imagingsensors. In particular, such sensors may be readily commerciallyavailable for visible-wavelength applications, and require nosignificant modification for use in system 500. In one example, FPAs528, 529 are commercially purchased CCD sensors having 2 Megapixelresolution. Some sensors for use in near-infrared applications arecurrently commercially available, albeit at substantially greater costthan the ubiquitous visible-wavelength sensors, and others are currentlybeing developed. It is anticipated that any of a variety of sensors,including those yet to be invented, may be used successfully in manyembodiments of the present invention. Optional FPA 632 may in someembodiments be the same as FPAs 528, 529.

However, sensors having a particular set of characteristics may in somecircumstances be preferred. For example, as noted above, providing afocal plane array in which each pixel has a deep electron well, e.g.,greater than 100,000 electrons, may enhance the signal to noise ratioobtainable by the system. The focal plane array also, or alternatively,may have a high dynamic range, e.g., greater than 40 dB, or greater than60 dB. Additionally, wells of such effective depths may be obtained bycombining the outputs of pixels of shallower depth (e.g., 4 pixels eachhaving a well depth of 25,000 or more electrons). Preferably, each pixelof the FPA is designed to substantially inhibit “blooming,” so that theelectrons of any pixels that may become saturated do not bleed over intoadjacent pixels.

C. Processor Subsystem 540

Referring again to FIG. 5, processor subsystem 540 includes controller541, storage 542, image constructor 543, GPS unit 544, and power supply545. Not all of such components need be present in all embodiments. Thefunctionalities of such components may alternatively be distributedamong other components of system 500, including but not limited toon-board processors on FPAs 528, 529. As described above, controller 541may be in operable communication with one or more elements ofillumination subsystem 510, such light source 511 and transmission (Tx)lens 512, and/or of sensor subsystem 520, such as receive (Rx) lens 521,optional FPA 532, modulator 524, and first and second FPAs 528, 529. Forexample, modulator 524 may be configured to modulate the polarization oflight pulse portions transmitted therethrough as a function of time,responsive to a control signal from controller 541. In one exemplaryembodiment, controller 541 sends a control signal to voltage source 750illustrated in FIG. 7A, which applies appropriate voltages to Pocketscells 721, . . . 728 via conductors 751, 752. Controller 541 is also inoperable communication with storage 542, image constructor 543, GPS unit544, and power supply 545.

Controller 541 is configured to obtain images from optional FPA 532 andfirst and second FPAs 528, 529 and to provide the images to storage 542for storage. Storage 542 may RAM, ROM, a hard drive, flash drive, or anyother suitable storage medium. Image constructor 543 is configured toobtain the stored images from storage 542 and to constructthree-dimensional images based thereon, as described in greater detailbelow. GPS 544 is configured to identify the position and/or attitude ofsystem 500 as it obtains images, and to provide such information tostorage 542 to be stored with the corresponding images. Additionally, anaccelerometer or other suitable attitude measuring device may be useddetermine an approximate change in attitude of the system 500 from oneframe to the next in a series of images. This information may be used aspart of a method to register the images to a global or relativereference frame. Power supply 545 is configured to provide power to theother components of processor subsystem 540, as well as to any poweredcomponents of illumination subsystem 510 and sensor subsystem 520.

Responsive to the control signal that controller 541 generates,modulator 524 generates a phase delay between orthogonal polarizationstates for pulse portions transmitted therethrough. The phase delay F isa function of time, and may be expressed by:

Γ=g(V(t))  (8)

where g is the response of modulator 524 as a function of voltage V, andV(t) is the applied voltage as a function of time. The intensityI_(528,i,j) of the modulated light pulse portion that is received atpixel (i,j) of first FPA 528 may be expressed as:

I _(528,i,j) =I _(total,i,j) cos²(Γ/2)  (9)

while the intensity I_(529,i,j) of the modulated light pulse portionreceived at pixel (i,j) of first FPA 529 may be expressed as:

I _(529,i,j) =I _(total) sin²(Γ/2)  (10)

where, in the embodiment illustrated in FIG. 5, I_(total,i,j) is equalto I_(528+529,i,j), which is the sum of the intensity received by pixel(i,j) of first FPA 528 and the intensity received by the correspondingpixel (i,j) of second FPA 529. In other words, I_(528+529,i,j) is thenon-modulated intensity that would be received by FPA 529 if polarizingbeamsplitter 527 were removed. Although I_(total,i,j) is computed basedon the sum of two complementary images in the embodiment of FIG. 5, inother embodiments I_(total,i,j) may be obtained by obtaining an image ofnon-modulated light, as described in greater detail below with referenceto FIG. 12.

The TOF t_(i,j) for each light pulse portion imaged at pixel (i,j),i.e., the time it took that portion to travel from illuminationsubsystem 510, to the scene, and to sensor subsystem 520, may bedetermined by solving for t (the pulse portions TOF) from equations (9)and (10), which may be expressed as follows:

$\begin{matrix}{t_{i,j} = {t_{0} + {V^{- 1}\left( {g^{- 1}\left( {2\; {\cos^{- 1}\left( \sqrt{\frac{I_{528,i,j}}{I_{{total},i,j}}} \right)}} \right)} \right)}}} & (11)\end{matrix}$

where t₀ is the time between when the light pulse leaves illuminationsubsystem 510 to when modulator 524 begins modulating the polarizationof light transmitted therethrough, e.g., t₀ represents a distance offsetfrom the device to the object in the scene. As discussed further below,t₀ may be determined using any one of several ranging techniques. Thedistance z_(i,j) of the object from which the pulse portion reflected orscattered may then be calculated as follows:

$\begin{matrix}{z_{i,j} = \frac{{ct}_{i,j}}{2}} & (12)\end{matrix}$

Where the functions V and g are monotonic functions of time, equations(11) and (12) have a unique solution for the distance z_(i,j). Thus,image constructor 543 may calculate the distance z_(i,j) for eachportion of each object in a scene by obtaining from storage 542 theimages respectively recorded by first and second FPAs 528, 529 andapplying equations (11) and (12) thereto. Note that such a calculationmay require knowledge of the inverse of the response function as afunction of time and voltage, g(V(t)), of modulator 524. In someembodiments, such information may be obtained by carefully calibratingthe system. An example of such a calibration is provided further below.

Where the functions V and g are not monotonic functions of time, thenadditional information may be used to determine which of the severalpossible values of z_(i,j) is the correct value for the pixel (i,j).There are many ways to obtain the additional information. For example,multiple wavelengths of light may be used to illuminate the scene. Thepolarization modulation Γ may be a different function of voltage foreach wavelength, which changes the intensity ratio for each wavelength.Another example is to have a second modulation arm (similar to thatdescribed below with respect to FIG. 11) with a second modulator, asecond polarizing beamsplitter, and a second pair of FPAs. The secondmodulator may apply a different voltage function of time, e.g., V₂(t).This would give another set of solutions for the distance z_(i,j) andonly the correct one will be present in both solution sets. Because thereflected light is typically not polarized, an initialpolarization-sensitive beamsplitter will already provide a secondoptical path where this second modulation arm may be positioned. Anotherexample is to use cues within the image itself to determine the correctdistance value. There are many techniques that are already used todetermine three-dimensional information from a two-dimensional image;these may be applied to enhance the performance. Additionally, if therelative positions of objects are known (e.g., because of perspectiveeffects) or it is known that the surface in question is continuous, thisinformation may also be used to determine the correct distance value.There are many other techniques as well that may be employed.

In some embodiments, the computation of distances z_(i,j) may besomewhat simplified by linearly modulating the voltage as a function oftime of a modulator based on the Pockels effect (e.g., Pockels assembly700 illustrated in FIG. 7A, or some other suitable modulator). In such amodulator, the polarization modulation Γ as a function of time may beexpressed as:

Γ=At  (13)

where A is a constant. Additionally, because the modulator is based onthe Pockels effect, the polarization modulation is a linear function ofthe applied voltage, and may be expressed as:

Γ=BV  (14)

where B is a constant that expresses the linear response function of themodulator as a function of voltage. For such a modulator, the distancez_(i,j) of an object from the three-dimensional imaging system 500 maybe expressed as:

$\begin{matrix}{z_{i,j} = {c{\frac{\cos^{- 1}\left( \frac{I_{528,i,j}}{I_{{total},i,j}} \right)}{AB}.}}} & (15)\end{matrix}$

The values of the constants A and B may be determined by calibrating thesystem and/or may be known properties of the modulator. The simplicityof such a calculation allows processor subsystem to obtain real-timedistance measurements, even with relatively simple electronics. Theresulting device thus may be relatively compact, more power efficient,and require no sophisticated post-processing to obtain the distancevalue for each pixel in the image, as compared to many other currenttechnologies. Such calculations alternatively may be performed using theon-board electronics within FPAs 528, 529.

In one embodiment, first and second discrete FPAs 528, 529 and imageconstructor 543 constitute a means for generating a first imagecorresponding to received light pulse portions and a second imagecorresponding to modulated received light pulse portions, which may beused to obtain a three-dimensional image based thereon. For example, thefirst image may correspond to the sum of two complementary modulatedimages obtained by FPAs 528, 529 (which sum may be computed by imageconstructor 543), and the second image may correspond to the imageobtained by FPA 529. In another embodiment, a single FPA and imageconstructor 543 constitute a means for generating a first imagecorresponding to received light pulse portions and a second imagecorresponding to modulated received light pulse portions, which may beused to obtain a three-dimensional image based thereon. For example, thefirst image may correspond to the sum of two complementary modulatedimages obtained by a single FPA (which sum may be computed by imageconstructor 543), and the second image may correspond to one of themodulated images. Such embodiments may include those in which modulatorsother than a Pockels cell-based modulator were used to modulate thelight pulse portions, e.g., an electro-optic Bragg deflector or othermodulator provided herein.

In another embodiment, first and second discrete FPAs 528, 529constitute a means for generating a first image corresponding toreceived light pulse portions and a second image corresponding tomodulated received light pulse portions. For example, the first imagemay correspond to the sum of two complementary modulated images obtainedby FPAs 528, 529 (which sum may be computed by on-board circuitry on oneor both of the FPAs), and the second image may correspond to the imageobtained by FPA 529. In yet another embodiment, a single FPA constitutesa means for generating a first image corresponding to received lightpulse portions and a second image corresponding to modulated receivedlight pulse portions, which may be used to obtain a three-dimensionalimage based thereon. For example, the first image may correspond to thesum of two complementary modulated images obtained by a single FPA(which sum may be computed by on-board circuitry on the FPA), and thesecond image may correspond to one of the modulated images. Suchembodiments may include those in which modulators other than a Pockelscell-based modulator were used to modulate the light pulse portions,e.g., an electro-optic Bragg deflector or any other modulator providedherein.

Note that the formulas expressed by equations (11), (12), and (15) arefor the “ideal” case. In the real world, there are systematic and randomerrors in the measured values, e.g., in I_(528,i,j), I_(520,i,j), t₀,and g(V(t)) or A and B. For example, it is known that all FPAs, whichconvert received photons into electrons that are then measuredelectronically, suffer from noise electrons arising from many effects,including thermal effects in the electronics. These noise electrons mayresult in a noise signal N that is independent of the number of incidentphotons at each pixel and may be characterized by a mean value with astandard deviation. In addition, the photons arriving at each pixelgenerate shot noise by causing quantum fluctuation of the pixel'selectromagnetic field. The standard deviation of this shot noise termgoes as the square root of the number of photons received. There alsomay be errors associated with light other than light generated byillumination subsystem 510 irradiating FPAs 528, 529.

Errors such as those listed above may reduce the resolution (or increasethe uncertainty) of the obtained distance measurements. Some embodimentsof the present invention include techniques that reduce the uncertaintyin the measured distance values, for example, to less than 5 mm in oneembodiment. For this purpose, the uncertainty is defined as the standarddeviation of the spread of values in the distance for a series ofidentical measurements.

As with other digital imaging techniques, the number of useful bits ofsignal available from the signal is equal to the total bits of signalminus the bits of noise signal, or equivalently the signal-to-noiseratio SNR). The SNR for a system may be expressed as:

$\begin{matrix}{{SNR} = \frac{I}{\sqrt{I + \sigma_{N\; 1}^{2} + \sigma_{N\; 2}^{2} + \ldots}}} & (16)\end{matrix}$

where σ_(N1) is the standard deviation of the noise from a first source,σ_(N2) is the standard deviation of the noise from a second source, andI is the intensity of the signal. The number of bits N_(sig) availableto characterize the distance may be expressed as:

N _(sig)=log₂ SNR  (17)

Because the error in the distance measurement is proportional to thesquare root of the SNR, in some embodiments image constructor 543 maycompute an error value for each pixel, and may indicate to the user, inreal time, whether any errors exceed a predetermined threshold. Such athreshold may in some circumstances be set by the user based on theparticular application. Responsive to the image constructor's indicationthat the errors exceed the predetermined threshold, the user may electto re-image the scene, potentially at a higher light energy. Incontrast, in previously known scanning techniques, it may not be knownfor some time whether all of the information about a scene was acquiredwith sufficient noise, e.g., may not be known until the point cloud isanalyzed, which may be well after the user has completed the imagingprocess.

In one embodiment of the present invention, the distance resolution isimproved by controlling the energy of light pulses that illuminationsubsystem 510 generates. Specifically, controller 541 may compare theintensity at the brightest portions of the images recorded by first andsecond FPAs 528, 529 to the saturation limit of the FPAs. If theintensity at the brightest portions is below some threshold percentageof the saturation limit of the FPAs, e.g., below 99%, or below 98%, orbelow 95%, or below 90%, of the saturation limit of the FPAs, thencontroller 541 may send a control signal to illumination subsystem 510instructing it to increase the energy of the generated light pulses to alevel at which the brightest portions of the images recorded by thefirst and second FPAs are at or above the threshold percentage of thesaturation limits of the FPAs, but below the saturation limit.Conversely, if the intensity at the brightest portions is at or abovethe saturation limit of the FPAs, then controller 541 may send a controlsignal to illumination subsystem 510 instructing it to decrease theenergy of the generated light pulses to a level at which the brightestportions of the images recorded by the first and second FPAs are belowthe saturation limits of the FPAs, but at or above the thresholdpercentage.

Controlling the pulse power to bring the brightest portions of the FPAimages close to the saturation limit may increase the SNR for the shotnoise, while at the same time dramatically increasing the SNR of thesignal as compared to the constant noise sources, such as electronicnoise. Because in many embodiments, three-dimensional imaging system 500is positioned relatively close to objects in the scene, significantlymore illuminating laser light is available for detection by the FPAsthan is available in previously known systems configured to obtaindistance information for remote objects. For example, whereas systemsconfigured to obtain distance information for remote targets, the amountof received light is relatively low, and the constant electronic noisemay detrimentally affect the data. For these previous devices, N_(sig)<5or worse, rendering the performance unsatisfactory for manyapplications. In contrast, in the described embodiment, monitoring theimage intensity and controlling the laser energy appropriately mayprovide a value of N_(sig)>9, an improvement of more than a factor often. Additionally, appropriately selecting an FPA with a high dynamicrange may provide a value of N_(sig) up to 20, for example.

For any given pair of complementary images, even if the brightestportions of the images are near the saturation limit of the FPAs, otherportions of the images may be insufficiently illuminated to accuratelycalculate the distances of objects imaged in those portions. Forexample, portions or all of an object may be highly absorptive at theirradiation wavelength, and so may reflect or scatter insufficient lighttoward sensor subsystem 520. Or, for example, an object may bereflective, but may be angled so as to reflect the light pulses awayfrom sensor subsystem 520. In such circumstances, it may be useful toobtain a sequence of images at varying pulse intensities, so as toincrease the resolution of a three-dimensional image of the scene. FIG.8 illustrates steps in a method 800 for increasing the resolution of animage of a scene. First, a light pulse of a first energy may begenerated, and the scene irradiated with same (810). The first energymay be selected so that at least some of the pulse portionsreflected/scattered by the scene are at or above the thresholdpercentage of the saturation limit, but below the saturation limit, ofthe FPAs. A first pair of complementary images of the scene are thenobtained and analyzed to obtain a three-dimensional image (820). Someobjects may be imaged with high resolution, because the SNR was high intheir portions of the image, while other objects may be imaged withinsufficient resolution, because the SNR was low in their portions ofthe image due to absorption or poor reflection, for example.

To obtain enhanced information about the objects that are insufficientlyresolved in the first three-dimensional image, the measurement may berepeated using a laser pulse of greater energy, to obtain a largeramount of light from the absorptive or poorly reflective objects.Specifically, a light pulse of a second energy may be generated and thescene irradiated with same (830). For example, controller 541 may send acontrol signal to illumination subsystem 510 instructing it to generatea light pulse of a specified increased energy. Alternatively, controller541 may send a control signal to a separate optical component in theoptical path of the light pulse, such as a variable intensity filter ora liquid crystal attenuator, instructing it to allow a greaterproportion of the light transmitted therethrough. The second energy maybe selected so that at least some of the pulse portionsreflected/scattered by the scene are above the saturation limit of theFPAs, e.g., are 10% or more, or 20% or more, or 50% or more, or 100% ormore, or 200% or more, or 500% or more, or 1000% or more, above thesaturation limit of the FPAs. Preferably, the FPAs are configured sothat any pixels that saturate substantially do not “bloom,” that is, donot leak photoelectrons onto adjacent pixels, giving the illusion ofhigher signal on those adjacent pixels.

A second pair of complementary images of the scene are then obtained andanalyzed to obtain a second three-dimensional image (840). The objectsthat were insufficiently resolved in the first three-dimensional imagemay be imaged with higher resolution in the second three-dimensionalimage, because their SNR may be improved by increasing the light pulseenergy for the second measurement. However, the second three-dimensionalimage may not contain usable information about other objects in thescene, such as those objects that were well-resolved in the first threedimensional image, because the pixels recording information of thoseobjects may have been saturated by the light pulse of the second energy.As such, the first and second three-dimensional images of the scene maybe combined to obtain a three dimensional image having increasedresolution as compared to the first and second three-dimensional images(850). Any suitable algorithm may be used to determine which portions ofthe first and second images to use or to discard as corresponding toinsufficiently resolved objects or saturated pixels. The measurementsmay be repeated using a variety of pulse energies so as to image eachobject in the scene with sufficient resolution. This method can berepeated over a series of frames, varying the level of saturation orexposure of FPAs 528, 529. This may be done for static scenes where thesystem 500 is not moving by properly combining the values at each pixel(i,j) from each of the several frames. In some embodiments, the system500 may be moving or the object(s) of interest may be moving so thatalgorithms will be used to register the corresponding pixels of eachframe to the pixels (i,j) of a master frame.

Note that method 800 illustrated in FIG. 8 may also be considered toincrease the dynamic range of system 500. For example, a first image mayinclude a signal of 1 to 100,000, which would correspond to N_(sig)=7.9,assuming a non-shot noise value of 10. A second image may be attenuatedby 100,000 so that it would measure a signal from 100,000 to 10¹⁰. Thisprovides another 8 bits so when the two images are combined,N_(sig)=15.9 bits.

The resolution and dynamic range of system 500 alternatively, oradditionally, may be increased by increasing the dynamic range of FPAs528, 529. For example, in one embodiment, the range of FPAs 528, 529 isincreased by leveraging the color filters commonly provided on FPAs forthe purpose of obtaining color images, such as Bayer filters. Aschematic of a Bayer filter 900 is illustrated in FIG. 9A. Filter 900includes a plurality of red filters (R), blue filters (B), and greenfilters (G). Each of the colored (R, B, or G) filters overlies acorresponding pixel on first or second FPAs 528, 529. FIG. 9Billustrates the spectral response curve for a commercially available FPAhaving a Bayer filter similar to that illustrated in FIG. 9A (KODAKKAI-16000 Color Image Sensor, Eastman Kodak Company, Rochester, N.Y.).For further details on Bayer filters, see U.S. Pat. No. 3,971,065, theentire contents of which are incorporated herein by reference.

As illustrated in FIG. 9B, pixels of the FPA covered by green filtershave a relatively large absolute quantum efficiency centered about 550nm. Thus, if illumination subsystem 511 generates light pulses in thegreen portion of the spectrum, e.g., at 532 nm, the green filters (G)the underlying FPA pixel will be highly responsive, e.g., will have anabsolute quantum efficiency of about 0.35. In contrast, those portionsof the FPA covered by blue filters have a relatively large absolutequantum efficiency centered about 465 nm, and a relatively lowefficiency at 532 nm, of approximately 0.10. Those portions of the FPAcovered by red filters have a relatively large absolute quantumefficiency centered about 620 nm, and a relatively low efficiency at 532nm, of less than about 0.01. Thus, if illumination subsystem 510generates light pulses at 532 nm, pixels covered by green filters willbe at least three times more responsive to reflected/scattered lightpulse portions than pixels covered by blue filters, and at least thirtytimes more responsive than pixels covered by red filters. Thus, formonochromatic light, such color filters may be used to expand thedynamic range and resolution of the FPAs by a factor of thirty or more.

In some embodiments in which the FPAs include a color filter such asBayer filter 900 illustrated in FIG. 9A, the energy of the light pulsegenerated by illumination subsystem 510 may be increased by 30 times ormore above that energy which would otherwise have been near thesaturation limit of the FPAs, to provide an effect similar to thatprovided by the method illustrated in FIG. 8, but without necessarilyrequiring the use of pulses of varying energies. Specifically, the pulseenergy may be increased to a level at which the least responsive pixels(e.g., the pixels covered by red filters) are at or above a thresholdpercentage of the saturation limit of those pixels. At such an energy,the least responsive pixels may satisfactorily image objects in thescene that reflect/scatter the most light. The information from thosepixels may be selected, e.g., based on a stored map of the filter, toconstruct a first image, similar to that produced at step 820 of FIG. 8.At this energy, the more highly responsive pixels (e.g., those coveredby green or blue filters) that receive photons from the highlyreflective/scattering objects in the scene may be saturated, while theleast responsive pixels may receive an insufficient amount of light tosatisfactorily resolve objects that are poorly reflective/scatteringobject. However, the more highly responsive pixels that receive photonsfrom such poorly reflective/scattering objects in the scene maysatisfactorily image such objects. The information from those pixels maybe selected to construct a second image, similar to that produced atstep 840 of FIG. 8. As many such images may be obtained as there arepixels of different responsiveness, and may be combined together toobtain a three dimensional image having increased resolution as comparedto the image obtained using any one type of pixel.

Of course, the method of FIG. 8 may also be used with FPAs having colorfilters, to further extend the dynamic range and resolution of thethree-dimensional imaging system. Additionally, filters other than aBayer filter may be used to expand the dynamic range of the FPAs. Forexample, other color filters may be used, which may be based on RBGfilters, CMYK filters, or other suitable filters, configured in anysuitable pattern. Or, for example, patterns of attenuation (grayscale)filters may be used, in which any suitable number of different levels ofattenuation (e.g., two or more, or three or more, or five or more, orten or more) are provided in any suitable pattern. However, the use ofBayer filters may in some circumstances be the lowest-cost alternativebecause Bayer filters are often provided as a standard component of FPAsconfigured for use in the visible region of the spectrum. Whicheverfilter is selected, the response of the individual pixels may becalibrated using standard color/grayscale correction techniques to forma color/grayscale matrix that may be stored in storage 542 and usedduring the construction of different images based on different pixels.Additionally, instead of using filters, some FPAs include multiplesensors of different sensitivities at each pixel. Alternatively, thelight collected by lens 521 may be separated into different opticalpaths, and the different optical paths attenuated by a known amount. AnFPA may be provided at the end of each optical path, analogous to theway multi-chip color cameras split the 3 colors into 3 paths to 3different FPAs. In such cases, the illuminating light pulse energy maybe selected so as to nearly saturate the brightest pixel in the FPAreceiving the most attenuated beam. As for the embodiment describedabove with reference to FIG. 8, controller 541 may send a control signalto illumination subsystem 510 that contain instructions on theappropriate pulse energy to be generated, or may send a control signalto an appropriate attenuation optic, if provided.

Another embodiment of the present invention makes use of binning pixelstogether to effectively achieve higher SNRs. For some FPAs, such asthose including complementary metal oxide semiconductors (CMOS), it ispossible to bin the pixels in to “superpixels” on the chip itself. Forother FPAs, such binning may be performed by image constructor 543 tomodify the information content of images in storage 542. By binningtogether 4 pixels, e.g., a 2 by 2 array of pixels, N_(sig) may beincreased by 2.

Another embodiment increases the SNR by averaging over time, e.g., byperforming boxcar averaging. In some embodiments, controller 541performs such averaging by integrating the reflected light from multiplelaser pulses in the pair of complementary images obtained by FPAs 528,529. In other embodiments, image constructor 543 performs such averagingby averaging the distance values in multiple stored three-dimensionalimages. Image constructor 543 may perform such image-to-image averagingeven if an object in the scene, or the imaging system, is moving, byregistering the pixels in each image to a single generalized coordinateframe of reference. Controller 541 and/or image constructor 543 may alsoapply other averaging and similar techniques to enhance the digitalimages and/or video, and these are generally applicable to the presentinvention to enhance the distance resolution. Controller 541 and/orimage constructor 543 may apply such image enhancement techniquestemporally across many pulses or images or spatially across many pixels,or both.

Systematic noise sources may also be present in system 500, such aspixel-to-pixel variation in the responses of FPAs 528 and 529, imperfectseparation of the orthogonal light components by polarizing beamsplitter527, and/or nonlinearities in the modulation of the reflected/scatteredpulse portions by modulator 524, which may result from nonlinearities inthe voltage ramp applied to modulator 524 and/or nonlinearities in thetemporal response of the modulator to applied voltage. Embodiments ofthe present invention reduce such systematic noise sources by carefullycalibrating system 500 following assembly. For example, the baselineresponse of the pixels of FPAs 528, 529 may be determined by using FPAs528, 529 to obtain images of a series of uniformly flat, nonpolarizingsurfaces having a specified range of reflectances, e.g., 10%, 20%, 30%,40%, 50%, 60%, 70%, 80%, 90%, and 100%. Such a series of imagesalternatively may be obtained by varying the energies of pulsesgenerated by illumination subsystem 510 by a similar series ofpercentages of the maximum energy. The levels used for calibration maybe selected so that the result is valid over the dynamic range of theFPAs and the device. The series of images may be analyzed to generate acurve for each pixel that may be used to correct the response of eachpixel so that the resulting image will be substantially uniform at eachlevel of incident light. Such curves may be stored, for example, as acalibration matrix in storage 542, and used by image constructor 543 tocorrect the two-dimensional intensity images before using them to formthree-dimensional images, such as illustrated in FIG. 3.

Suitable calibration techniques also may be used to accurately registerthe pixels of FPAs 528, 529. For example, a set of precision targets,whose centroid may be determined to a precision of much smaller than asingle pixel (e.g., a sphere) may be imaged with the two FPAs. The FPAsmay be mechanically adjusted (e.g., adjusted in the x, y, and ddirections, along with tip and tilt) to register the images together,and/or any offsets may be electronically adjusted for (e.g., using imageconstructor 543).

As explained above with reference to equations (11) and (12), knowledgeof the time- and voltage-dependent response function g(V(t)) ofmodulator 524 and time delay t_(o) may be used to accurately obtaininformation about the distances of objects in the scene. Such a responsefunction and time delay may in some embodiments be calibrated by makinga series of measurements of a flat target, in which the target is movedbetween a range of distances that cover the total distance “depth offield” (distance window) that will be used for the application and thedevice. For example, if the modulator is to be generally linearlymodulated over a time period corresponding to distances of 5 to 10meters from the system, the calibration target may be positioned at 5meters, 6 meters, 7 meters, 8 meters, 9 meters, and 10 meters from thedevice. As the pulse reflects off of the target at each position, thepulse's TOF will vary, so the pulse will experience a different timedelay and portion of the modulation response function g(V(t)) ofmodulator 524. Because z_(i,j) and t_(i,j) are known from thecalibration, g(V(t)) and t₀ may be calculated based on the intensity ateach pixel i,j for FPAs 528, 529. A calibration curve for g(V(t)) may bestored, for example, in storage 542, and used by image constructor 543to correct the two-dimensional intensity images before using them toform three-dimensional images, such as illustrated in FIG. 3.

Alternatively, a series of internal optical delays may be used togenerate light pulses at a specific series of delays from the mainilluminating light pulse. These optical delays may be routed internallyto the device such that they pass through modulator 524 and on to FPAs528, 529 when desired, e.g., responsive to a control signal bycontroller 541. These delays will correspond to precise distances thatcan produce the retardation delay functions g(V(t)) similar to theabove-described embodiment. Alternatively, system 500 may includeoptical elements arranged so as to produce delays of sufficient length,after many bounces, over some geometric shape such as a wedge or line.In some embodiments, short pulse laser diodes may be triggered to emitshort pulses (e.g. <1 ns) at specific intervals during the time window.In some embodiments, the optical delays may be created by splitting thecalibration pulse into one of several optical fibers of determinedlengths.

In addition to employing any of a variety of techniques to enhance theresolution of the three-dimensional images, controller 541 may furtherenhance the range of such images, which may also be referred to as the“depth of field” (DOF) or “distance window” of the images. Increasingthe depth of field of an image may be especially useful when the systemis used to obtain three-dimensional images or movies of complex scenesin which objects in the scene are positioned across a range ofdistances. For example, as noted above with reference to FIG. 2, themodulation of pulse portions reflected/scattered by the scene may occurover a temporal window having a defined start time and defined duration,which correspond to a defined distance window. If the system werelimited to acquiring information about objects only within such adistance window, its applicability might be limited.

First, the depth of field may be set to larger than other devicesproduced, such as that of Taboada, because system 500 has a largerdynamic range. Because N_(sig) is significantly larger, increaseddistance resolution may be achieved while simultaneously setting themodulation period to be larger, yielding a greater depth of field.

Additionally, FIG. 10 illustrates an “adaptive depth of field” method bywhich controller 541 of FIG. 5 may further extend the distance window ofa three dimensional image. For example, it may be desired to obtain animage of a scene over a distance window (depth of field) between 5 and55 meters from the imaging system 500, but the distance window of anysingle frame may be limited to 10 meters in order to achieve the desireddistance resolution. To obtain a three-dimensional image having anincreased range as compared to that obtainable with a single frame, thescene may first be irradiated with a first light pulse (1010), forexample responsive to a control signal that controller 541 transmits toillumination subsystem 540. As the portions of the first light pulsereflected/scattered by the scene are transmitted through modulator 524,the polarization of those portions are modulated over a first temporalwindow (1020). Such a temporal window may, for example, be selected tocorrespond to a distance window of 10 meters, beginning at a distance of5 meters from the imaging system. A first three-dimensional image isobtained based on the modulated portions of the first light pulse(1030), for example using image constructor 543. Continuing with theexample provided above, such an image may for example containinformation about objects positioned 5-15 meters from the imagingsystem.

The scene may then be irradiated with a second light pulse (1040), whichin some embodiments may be of substantially the same energy as the firstlight pulse. As the portions of the second light pulsereflected/scattered by the scene are transmitted through modulator 524,the polarization of those portions are modulated over a second temporalwindow (1050). Such a second temporal window may begin and end at anydesired time, for example, may overlap with the first temporal window,or may be immediately before or after the first temporal window. Thesecond temporal window may have the same duration as the first temporalwindow, or may be longer or shorter, as appropriate.

For example, the first temporal window may be selected to collectinformation about a first distance window of the scene that containslittle information of interest, and so may have a broadened temporalduration (corresponding to a lower resolution), whereas the secondtemporal window may be selected to collect information about a seconddistance window of the scene that contains an object of interest, and somay have a shortened temporal duration (corresponding to a higherresolution). A second three-dimensional image is then obtained based onthe modulated portions of the second light pulse (1060). Continuing withthe example provided above, the second image may contain informationabout objects positioned 15-25 meters from the imaging system. Anydesired number of additional images may be obtained by repeating steps1040 to 1060 over other modulation windows. The first and second images(as well as any other images) may be combined to obtain athree-dimensional image having increased range as compared to the firstand second images (1070).

The method illustrated in FIG. 10, like other methods described herein,may also be applied to the acquisition of movies. Such movies may, forexample, contain an object that moves over time relative to acomparatively stationary background, where the moving object is ofprimary interest and is located within a particular distance window (thelocation of which may shift over time). The scene may be irradiated witha first pulse, the reflected/scattered portions of which are modulatedover a first time window selected to correspond to all or a portion ofthe background, to form a first three-dimensional image. The scene thenmay be irradiated with a second pulse, the reflected/scattered portionsof which are modulated over a second time window selected to encompassthe moving object of interest, to form a second three-dimensional image.The second time window may be related in any desired way to the firsttime window. For example, the second time window may be narrower thanthe first time window to obtain information about the moving object withhigher resolution than the background. The second time window may alsobe completely or partially encompassed by the first time window, so thatthe second image contains some of the information contained in the firstimage, although at higher resolution. Alternatively, the second timewindow may be nonoverlapping with the first time window, so as tocontain information about a separate, nonoverlapping spatial region ofthe scene. The first and second images may be combined to form athree-dimensional image that constitutes a first three-dimensional frameof the movie.

The scene may then be irradiated with a third pulse, thereflected/scattered portions of which are modulated over a third timewindow selected to encompass the moving object of interest, to form athird three-dimensional image. The third time window may, for example,be the same as the second time window, or may overlap with the secondtime window, or may be nonoverlapping with the second time window,depending on how quickly the object of interest is moving. The thirdimage may be combined with the first image to form a three-dimensionalimaged that constitutes a second three-dimensional frame of the movie.Because the background is unchanging, or changing relatively slowly ascompared to the object of interest, the background image (the firstimage) may be used to form several frames of the movie without losinginformation about the object of interest, and thus may reduce the timeand computation involved in acquiring a series of three-dimensionalmovie frames. Such background images may be acquired at any desiredrate, which may be some fraction of the rate at which images of themoving object are acquired, for example, at half the rate, or at a thirdof the rate, or a quarter of the rate, or a fifth of the rate, or atenth of the rate.

Additionally, although some of the above-described embodiments linearlymodulate the polarization of the reflected/scattered pulse portions,other modulation waveforms, including non-monotonic (but not necessarilyperiodic) waveforms such as a sine wave or a sawtooth, may effectivelybe used to increase the depth of field of the three-dimensional imagingsystem. For example, with reference to FIG. 11, alternative system 1100includes receiving (Rx) lens 1121 and band-pass filter (BPF) 1122, whichmay be similar to the corresponding elements in FIG. 5, and first andsecond modulation arms 1110, 1120. System 1100 optionally may alsoinclude a visible imaging subsystem such as that illustrated in FIG. 5,but omitted in FIG. 11 for simplicity.

System 1100 includes beamsplitter 1123, which optionally is a polarizingbeamsplitter and which allows some of the light from band-pass filter1122 to be transmitted to first modulation min 1120, and redirects otherof the light from the band-pass filter to second modulation arm 1110.First modulation arm 1120 includes modulator 1124, compensator (Cp.)1125, imaging lens 1126, polarizing beamsplitter 1127, and first andsecond FPAs 1128, 1129, each of which may be the same as thecorresponding components discussed above with reference to FIG. 5.Second modulation arm 1110 includes modulator 1114, compensator (Cp.)1115, imaging lens 1116, polarizing beamsplitter 1117, and first andsecond FPAs 1118, 1119, each of which may be the same as thecorresponding components in first modulation arm 1120. System 1100 mayalso include an illumination subsystem and an image processing subsystemthat includes a controller, which may be the same as those describedabove with reference to FIG. 5. In some embodiments, either themodulation arm 1110 or the modulation arm 1120 may only use a single FPA1119 or 1129, respectively, because the normalization image may beobtained from the other arm.

During operation, the controller (not illustrated) of system 1100 maysend different control signals to modulator 1124 than to modulator 1115.For example, the controller may send a control signal to modulator 1124instructing it to vary the polarization of pulse portions transmittedtherethrough monotonically as a function of time. In comparison, thecontroller may send a control signal to modulator 1114 instructing it tovary the polarization of pulse portions transmitted therethroughnon-monotonically, e.g., using a sine wave or sawtooth function thatrepeats multiple times during the duration of the single monotonicmodulation of modulator 1124. The images obtained by FPAs 1128, 1129 onfirst modulation arm 1120 may contain information about a relativelywide distance window, e.g., a 50 meter window. Because this arm does notneed to achieve the same resolution, in some embodiments it may beuseful to choose beamsplitter 1123 such that the fraction of light goingto this arm is <50%. In contrast, the images obtained by FPAs 1118, 1119on second modulation arm 1110 may contain information about a relativelynarrower distance window that is encompassed by the wider distancewindow obtained by the first modulation arm. Information in the imageobtained by the first modulation arm may be used to fix the position ofobjects in the image obtained by the second modulation arm, thusproviding for simultaneous three-dimensional measurement across theentire depth of field.

In another embodiment, the initial distance to a key feature may bedetermined approximately by a single ranging photodiode or severalphotodiodes during the previous frame. The timing of the center of themodulation period for subsequent frames may be set in one of severalways. For example, it may be set to the initial value, or may be setbased on a trend of a key feature in a series of previous frames, or maybe set using optical auto-focus techniques. If more than one rangingdiode or auto-focus position is used, algorithms similar to those usedin optical auto-focus mechanisms to perform a weighted average of thesemultiple sites or diodes may be used.

In combination with these embodiments, the length of the depth of field(distance window) may be adjusted as appropriate, e.g., by varying theduration of the pulse portion modulation imparted by modulator 524responsive to control signals from controller 541 in FIG. 5. Inaddition, if it is desired to obtain higher distance resolution over acertain region of the DOF, the slope of the modulation may be increasedin that region. The slope may then be decreased during the remainder ofthe modulation period, producing a lower distance resolution in otherareas of the scene where the greater resolution is not needed. It shouldbe appreciated that there are many combinations that may be used toachieve a satisfactory three-dimensional image or movie.

As previously mentioned, the three-dimensional images may be registeredto a global coordinate reference frame, if desired, either GPS-based orsome other desired reference frame. Such registration may provide theability to use the data from different frames to perform imageenhancement algorithms. It also may provide a mechanism to use the imageand video information from several frames to create a substantiallycomplete three-dimensional representation of the scene or object(s)within the scene. This may be done from different perspectives. Forexample, an object or group of objects may rotate about some axis suchthat after a certain number of frames, all sides of the object(s) havebeen imaged. The rotation need not be uniform. The data from the imagesmay then be assembled into a full three-dimensional representation ofthe surfaces of the object. Alternatively, the user of the imagingsystem 500 may move the camera around the object(s) of interest andthereby obtain all necessary 3D image information. In some embodiments,several imaging systems 500 can be placed around object(s) of interestand the 3D images from these systems can be combined to create a fullthree-dimensional representation of the surfaces of the object(s). Itthen may be viewed as if it were a solid object(s), and all sides may beviewed in detail using 3D manipulation software.

In various embodiments of the invention, any suitable technique may beused to register the frames of the various FPAs with one other. Forexample, digital video cameras use software to remove motion blur fromframe to frame. This technique is known as image stabilization, andalternatively may be employed in the present invention to register thepoints in subsequent three-dimensional frames to points in a first (orreference) frame.

In general, various embodiments of the invention make use of other 3Dprocessing techniques to improve the distance resolution and performanceof the system. For example, one embodiment uses known techniques toextract distance information from the image information. Examples ofsuch image information include perspective cues and shadow cues, whichare currently used to extract some low resolution 3D information fromexisting 2D still and video images. Data from such cues may be employedin the present invention (e.g., implemented by image constructor 543) toimprove the distance resolution and improve the depth of field (distancewindow) of the system.

Another embodiment uses techniques such as stereophotogrammetry if thereare multiple three-dimensional imaging devices being used to image thesame scene. Or, if the imaging device is moving with respect to thescene, another embodiment may employ triangulation from differentviewpoints to calculate depth. The resulting data may be used to improvethe distance resolution obtained from the time of flight technique andto extend the depth of field (depth window).

Another embodiment measures the polarization state of the light pulseportions reflected/scattered by objects the scene. Such polarizationstates may, in some circumstances, contain additional information aboutobjects in the scene. For example, natural objects tend to change thepolarization state of light they reflect, while man-made objects tendnot to do so. There may be techniques to use such polarizationinformation to determine the direction of the surface normal of theobject area imaged at a given pixel. This surface normal and the changein the surface normal from pixel-to-pixel may be used to improve thedistance resolution and extend the depth of field. In one embodiment,the polarization state of the light pulse portions reflected/scatteredby objects in the scene may be determined by modifying system 1100,illustrated in FIG. 11, to replace beamsplitter 1123 with a polarizingbeamsplitter. Any light that experienced a polarization rotation uponinteraction with objects in the scene may be directed onto the secondmodulation arm 1110, while light that did not experience a polarizationrotation may be transmitted onto the first modulation arm 1120. Thecontroller (not illustrated) may send substantially the same controlsignals to both modulators 1124, 1114, e.g., instructing the modulatorsto monotonically (for example, linearly) vary the polarization of lighttransmitted therethrough over a defined temporal window, such asillustrated in FIG. 2. Thus, the FPAs on both of the modulation arms1120, 1110 may obtain two-dimensional intensity images of generally thesame scene, over substantially the same distance window. However, theimages obtained by FPAs 1118, 1119 on the second modulation arm 1110will substantially only contain information objects that changed thepolarization of the incident light. Such information may be combinedwith the three-dimensional image obtained using the images from FPAs1128, 1129 to produce an image having enhanced information content.

In general, three-dimensional information about a scene may be obtainedusing any number of different modalities, each of different quality,spatial scale, resolution, and sensitivities. Embodiments of theinvention may take advantage of any or all of this information by usinginformation theory and image processing algorithms to combine thisinformation into a single representation of the scene. The differentscales and sensitivities of the information may be useful in thisrespect. The result is to improve the distance and spatial resolutionand to extend the depth of field as well as improve the color or greyscale imagery and video.

Another aspect of enhancing the performance of systems such as system500 illustrated in FIG. 5, or system 1100 illustrated in FIG. 11,pertains to controlling uncertainties related to the temporal andthermal behavior of the electronic components of the system. This mayinclude timing circuits, the modulation waveform, and the focal planearray circuitry. Some of such control may be based on the processorsubsystem, while other of such control may be based on the design ofother components in the system.

For example, to achieve an uncertainty of less than 0.1% in rangeresolution across a segment of the waveform may be known to 1 part in1000, or to within 0.1%. This may be accomplished either by circuitdesigns so that the waveform does not vary from image to image by morethan the desired uncertainty, or by including a circuit that measuresand digitizes each waveform to less than the desired uncertainty. Thismay also apply to any delays that may exist within the system, such asthe time delay that may be present for the waveform's applied voltagesto propagate across the aperture of the Pockels cell (or Pockelsassembly).

The timing circuitry that determines the delay between the laser pulseand the start of the modulation waveform may be made more precise thanthe desired uncertainty of the range measurement. This type of timingerror only affects absolute accuracy, not the relative accuracy betweenobjects in a single frame. As part of this, the timing of the laserpulse may be measured to at least as precisely. One way to accomplishthis is to use a laser design that ensures that there is only one globalpeak in the laser temporal profile and that the temporal profile isrelatively smooth by ensuring either a single temporal mode, or thatmany temporal modes (e.g., more than 20, more than 30, or more than 50)are present. Then, a peak detect algorithm (which may be performed bythe processor subsystem) may identify the temporal position of the peakto some fraction of the laser pulse length. In some embodiments, athreshold algorithm may be used rather than a peak-detect algorithm todetermine the temporal position of the laser pulse. The signal of thelaser pulse will be collected by a single fast photodiode and ananalog-to-digital converter with digital resolution below the desireduncertainty. In one illustrative embodiment, the position of the peak ofthe laser pulse, or other identifiable portion of the laser pulse, isidentified with an error of less than 3 picoseconds. The time lapsebetween the laser pulse and the beginning of the modulation waveform maythen be controlled with an error of less than 3 picoseconds.

The readout circuitry and gain values in the focal plane arrays may alsobe known from frame to frame to a lower uncertainty than is desired forthe range measurement. Provided that the behavior does not changesignificantly from image to image or pulse to pulse, the behavior of thereadout and gain circuitry with respect to measured signal at each pixelmay be measured using calibration targets to remove any systematicerrors by calibration.

There are many variations and embodiments to the general design toaccomplish three-dimensional measurement. In addition, range performancemay be improved by averaging and other noise reduction techniques beyondthose described herein. In some embodiments, it may be preferable tocontrol any or all timing variations within the system to better than0.1%.

4. Applications

It is anticipated that the three-dimensional imaging systems and methodsprovided herein may be used successfully in a wide variety ofindustries, including shipbuilding, civil construction, road surveying,utility corridor mapping, forensics and law enforcement, heavy industry,industrial construction, video games, motion pictures, motion picturespecial effects, archaeology, medical imaging, facial recognition,machine vision, quality control, aerospace and automotive components,medical prosthetics, dentistry, sports, sports medicine, among others.For example, the CyARK foundation is endeavoring to digitally preservethree-dimensional information about the vast number of disappearinghistorical sites throughout the world. The inventive systems and methodsmay drastically increase the rate at which such information may beacquired, while improving the quality of the information. Or, forexample, existing structures may be surveyed to obtain as-builtinformation, which optionally may be used to design retro-fits,renovations, and other construction work. Or, for example, the miningindustry may use the systems and methods to determine volumes ofmaterial removed, or the structure of a mine area. Or, for example, thecivil and transportation industry may use the systems and methods toprovide a cost-effective method for monitoring transportation and civilinfrastructure to identify failing structures (e.g. bridges, buildings,pipelines) prior to catastrophic events.

5. Alternative Embodiments

Although the embodiments described above include refractive optics,analogous embodiments may be constructed that utilize reflective opticsin place of one or more of the refractive optics.

Not all embodiments require the use of a pair of FPAs to recordcomplementary intensity images. For example, Yafuso (U.S. Pat. No.7,301,138, the entire contents of which are incorporated herein byreference) discloses the use of a prism to produce two complementarypolarization images on a single camera. In one embodiment, withreference to FIG. 5, polarizing beamsplitter 527 and FPA 528 may beomitted, and a prism such as disclosed by Yafuso included betweenimaging lens 526 and FPA 529. The prism is configured to direct the twocomplementary polarization images onto FPA 529, which is preferablysized to record both images. Controller 541 may obtain the pair ofsimultaneously recorded images from FPA 529 and provide them to storage542, which later may be accessed by image constructor 543, which mayseparately analyze and the two images. Suitable calibration techniquesmay be used to accurately register the pixels that record the firstimage with those that record the second image. For example, a set ofprecision targets, whose centroid may be determined to a precision ofmuch smaller than a single pixel (e.g., a sphere) may be imaged in twodifferent locations on the FPA. The tip, tilt, pincushion, and keystoneof the two images may be brought into registration using software (e.g.,image constructor 543).

FIG. 12 illustrates an alternative sensor subsystem 1220 that may, forexample, be used in place of sensor subsystem 520 illustrated in FIG. 5.Sensor subsystem 1220 optionally may include visible imaging subsystem530, omitted from FIG. 12 for clarity. Sensor subsystem includereceiving (Rx.) lens 1221, band-pass filter (BPF) 1222, modulator 1224,compensator (Cp.) 1225, imaging lens 1226, polarizing beamsplitter 1227,and FPA 1229, each of which may be the same as described above withrespect to the corresponding components illustrated in FIG. 5. However,sensor subsystem 1220 also includes beamsplitter 1223 which is at anysuitable position before the modulator (here, between bandpass filter1222 and modulator 1224), which directs a portion of the received lightto FPA 1219, which obtains an image of the scene based thereon. Theremainder of the light is transmitted to modulator 1224, which modulatesthe light transmitted therethrough, and FPA 1229 obtains an image of thescene based thereon. The images obtained by FPA 1219 and FPA 1229 differin that the former is based on unmodulated light, while the latter isbased on modulated light. The image obtained by FPA 1219 may be used tonormalize the image obtained by FPA 1229. Specifically, the intensity atany pixel (i,j) of FPA 1219 may be used as the value I_(total,i,j) inthe distance calculations discussed above with reference to equations(8) to (15). In contrast, for the embodiment illustrated in FIG. 5, thevalue I_(total,i,j) may be calculated by summing the complementaryimages obtained by FPAs 528, 529. It should be noted that in anyalternative embodiment in which a non-modulated image is obtained, theintensity of that image at each pixel (i,j) may be used as the valueI_(total,i,j) against which a modulated image may be normalized toobtain distance values, e.g., using equations (8) to (15).

In one embodiment, first and second discrete FPAs 1219, 1229 constitutea means for generating a first image corresponding to received lightpulse portions and a second image corresponding to modulated receivedlight pulse portions. For example, the first image may correspond to thenonmodulated image obtained by FPA 1219, and the second image maycorrespond to the modulated image obtained by FPA 1229. In anotherembodiment, a single FPA constitutes a means for generating a firstimage corresponding to received light pulse portions and a second imagecorresponding to modulated received light pulse portions. For example,the first image may correspond to a non-modulated image obtained by theFPA, and the second image may correspond to a modulated image obtainedby the same FPA.

While preferred embodiments of the invention are described herein, itwill be apparent to one skilled in the art that various changes andmodifications may be made. The appended claims are intended to cover allsuch changes and modifications that fall within the true spirit andscope of the invention.

What is claimed is:
 1. A three-dimensional imaging system, comprising:an illumination subsystem configured to emit a light pulse with adivergence sufficient to irradiate a scene having a wide field of view;a sensor subsystem configured to receive over a wide field of viewportions of the light pulse reflected or scattered by the scene, thesensor subsystem comprising: a modulator configured to modulate as afunction of time an intensity of the received light pulse portions toform modulated received light pulse portions; and means for generating afirst image corresponding to the received light pulse portions and asecond image corresponding to the modulated received light pulseportions; and a processor subsystem configured to obtain athree-dimensional image based on the first and second images.
 2. Thesystem of claim 1, wherein the means for generating comprises first andsecond discrete arrays of light sensors.
 3. The system of claim 2,wherein the means for generating further comprises an image constructor.4. The system of claim 1, wherein the means for generating comprises asingle array of light sensors.
 5. The system of claim 1, wherein thelight pulse has a duration of less than 2 nanoseconds.
 6. The system ofclaim 1, wherein the divergence is between 1 and 180 degrees.
 7. Thesystem of claim 1, wherein the divergence is between 5 and 40 degrees.8. The system of claim 1, wherein the illumination subsystem comprises alow-coherence laser configured to generate light pulses containing asufficient number of spatial modes to produce a smooth spatial profile.9. The system of claim 1, wherein the light pulse contains a wavelengthbetween 1400 nm and 2500 nm.
 10. The system of claim 1, wherein themodulator comprises a Pockels cell.
 11. The system of claim 1, whereinthe processor subsystem comprises a controller configured to send acontrol signal to the modulator, the modulator configured to modulatethe received light pulse portions monotonically as a function of timeresponsive to the control signal.
 12. The system of claim 1, wherein theprocessor subsystem comprises a controller configured to send a controlsignal to the modulator, the modulator configured to modulate thereceived light pulse portions non-monotonically as a function of timeresponsive to the control signal.
 13. The system of claim 1, wherein themeans for generating includes at least one focal plane array comprisinga plurality of pixels, each pixel having a well depth of 100,000 or moreelectrons.
 14. The system of claim 1, wherein the means for generatingincludes at least one focal plane array comprising a plurality ofpixels, and further comprising a filter having a plurality of regions,each region positioned in front of a pixel and configured to attenuatelight transmitted to that pixel in a predetermined fashion.
 15. Thesystem of claim 1, wherein the sensor subsystem further comprises abroadband or multiband imaging subsystem, the imaging subsystemcomprising: an image sensor configured to obtain a broadband ormultiband image of the scene; and an optic configured to direct aportion of the received light to the image sensor.
 16. The system ofclaim 1, wherein at least one of the first and second images contains aregion of maximum intensity, wherein the means for generating comprisesa sensor array having a saturation limit, and wherein the system isconfigured to enhance a dynamic range of the three-dimensional image byincreasing an energy of the light pulse above the saturation limit ofthe sensor array.
 17. The system of claim 1, wherein the processorsubsystem is configured to: instruct the illumination subsystem to emita plurality of light pulses; adjust a timing of the modulator such thatmodulation begins at a different time for each light pulse of theplurality of light pulses; obtain a plurality of three-dimensionalimages corresponding to each light pulse of the plurality of lightpulses; and obtain an enhanced three-dimensional image based on theplurality of three-dimensional images, the enhanced three-dimensionalimage corresponding to a larger distance window than a distance windowof any of the plurality of three-dimensional images.
 18. A method ofthree-dimensional imaging, comprising: emitting a light pulse having adivergence sufficient to irradiate a scene having a wide field of view;receiving over a wide field of view portions of the light pulsereflected or scattered by the scene; modulating with a modulator thereceived light pulse portions as a function of time to form modulatedreceived light pulse portions; generating a first image corresponding tothe received light pulse portions; generating a second imagecorresponding to the modulated received light pulse portions; andobtaining a three-dimensional image of the scene based on the first andsecond images.
 19. The method of claim 18, wherein generating the firstimage comprises adding the second image to a third image.
 20. The methodof claim 18, wherein modulating with the modulator comprises modulatinga polarization state of the received light pulse portions.